Head and neck paragangliomas (HNPs) are tumors of the autonomic system. They arise from chromaffin cells of the parasympathetic paraganglia of the skull base and neck, and are also called glomus tumors (1–5). Most well known is the tumor of the glomus caroticum, the carotid body tumor (CBT). HNP surgery is a challenge to the surgeon because of the tumor's location in the vicinity of important blood vessels and cranial nerves. As well as pre-operative impairment of nerve function, surgery may result in deficits of cranial nerves VII, VIII, IX, X, XI, and XII.

In this review, we present an overview of the clinical presentation and radiologic imaging of HNPs, topographical classification of HNPs, and recent advances in the genetics of HNPs in the context of nine susceptibility genes predisposing to tumors of the paraganglial system. These genetic data not only enrich our understanding of HNPs, but also provide us with a tool for risk assessment of tumors outside the head and neck region.

HNPs are rare tumors, representing less than 0.5% of all head and neck tumors. Approximately 3% of paragangliomas occur in the head and neck area (4); other estimates suggest that 1 in 30,000 head and neck tumors are HNPs (5).

Most HNPs arise in the bifurcation of the carotid artery (i.e. CBTs). Vagal paragangliomas arise from the autonomic nervous part of the vagal nerve (cranial nerve X). HNPs arising in the petrous bone originate from the tympanic glomus or the jugular glomus. When these tumors cannot be differentiated, they are referred to as jugulotympanic paragangliomas. Given the extensive spreading of the autonomic nervous structure, HNPs can arise at other locations, such as the ciliary glomus or laryngic glomus.

HNPs are space-occupying tumors. Signs and symptoms are induced by the topography of the anatomical structures from which the tumors originate. In contrast to extra-adrenal, abdominal, and thoracic pheochromocytomas, HNPs rarely secrete active substances. Only 1–3% of HNPs are vasoactive and associated with elevated catecholamines. Such tumors can induce tachycardia, hypertension and sweating attacks.

B-mode sonography and color duplex sonography are inexpensive, noninvasive diagnostic tools that are often used as the first imaging step for cervical HNPs (1),(14). A CBT is usually sonographically seen as a solid, well-defined, hypoechoic mass with a splaying of the carotid bifurcation (1). The external carotid artery (ECA) is usually displaced anteromedially, and the internal carotid artery (ICA) is typically displaced posterolaterally (15).

VPs tend to displace both the ECA and the ICA anteriorly. The internal jugular vein is typically compressed and displaced posteriorly (15). In large VPs there may also be a splaying of the carotid bifurcation, thereby mimicking a CBT.

In color duplex sonography scans, cervical HNPs present as hypervascular tumors in most cases. It is important to mention, however, that absence of hypervascularity does not exclude a cervical HNP (16). In a study on 18 CBTs, 15 (83.3%) presented as a hypervascular mass in color duplex sonography scans (16).

Carotid, tympanic, and jugular paragangliomas are easily detected using CT and MR angiography. They contain many arterio-venous shunts and show strong enhancement with CT-angiography. Using time-resolved contrast-enhanced MR-angiography, they are detected in the early arterial phase (Figure 2D). Tympanic paragangliomas are seen on high resolution CT images of the petrous bone as a focal soft-tissue mass in the tympanon (17). CT is superior for the detection of bone destruction in the temporal bone (18). For jugular paragangliomas both MR (17) and CT (19) are recommended. CT-angiography depicts the anatomy more accurately than MR-angiography because of the better spatial resolution (19). However, contrast-enhanced MR-angiography is better suited for screening and detection of multiple lesions. Both cross-sectional methods can be used for operative navigation. Pre-operative embolization of the paragangliomas aims for a reduction of blood loss during operation, but the literature is controversial (7),(20).

Figure 2.

Fisch classification. The tumors are indicated by yellow arrows. (A) Tympanic paraganglioma (Fisch class A): axial CT scan of a tympanic paraganglioma (bone window) on the right promontory. Note the absence of any bony erosion. (B) Tympanic paraganglioma (Fisch class B): the axial CT scan reveals a left-sided tympanic paraganglioma surrounding and partially destroying the ossicles. The malleus and stapes could not be discriminated. The tumor had also invaded the hypotympanon. There was no destruction of the bone wall to the jugular bulb. (C) Jugular paraganglioma (Fisch class C): axial CT scan showing a left-sided jugular paraganglioma. Note the bone destruction between the jugular bulb and the soft tissue tumor in the hypotympanon. (D) Tympanic paraganglioma (Fisch class D): time-resolved contrast-enhanced MR-angiography (upper row) depicts an early venous drainage attributed to arterio-venous fistulas within this tympanic paraganglioma (solid arrows). Coronal CT (lower row left) of the petrous bone shows a soft tissue tumor with encasement of the ossicles within the whole tympanon, and destruction of the tegmen tympani. Coronal T2-weighted and contrast enhanced T1-weighted images show a small, but distinct, intracranial but extradural tumor growth on the lateral skull base (dotted arrows, lower row).

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HNPs typically show avid uptake with different functional imaging techniques, namely 18F-fluorodihydroxyphenylalanine (18F-FDOPA) positron emission tomography/computed tomography (PET/CT); 18F-fluorodopamine (18F-FDA) PET/CT and 123I-metaiodobenzylguanidine (123I-MIBG) scintigraphy; the latter is paraganglioma specific. Furthermore, somatostatin receptor imaging has a sensitivity of greater than 90% for HNP (21) using 111In-octreotide scintigraphy. Positron emitting somatostatin receptor imaging agents, such as 68Ga-DOTA-peptides [e.g. 68Ga-DOTA-TATE (DOTA-Tyr3-Thr8-octreotide)] have shown promising sensitivities in small series (22). It offers an additional advantage in identifying patients likely to benefit from therapy with 90Y-labelled DOTA-TATE. 18F-FDOPA PET, in particular, has been proved to be highly sensitive in different series and may be considered a good imaging technique for HNPs (23) but may perform poorly in SDHB-associated metastatic disease; under these conditions, 18F-FDG-PET/CT provides higher sensitivities (24).

CBTs are usually classified using the criteria described by Shamblin and co-workers (25).

Shamblin classification

Shamblin Class I CBTs are localized tumors with splaying of the carotid bifurcation, but little attachment to the carotid vessels. Complete surgical resection is generally possible with only minimal risk of vascular or cranial nerve complications (1).

Shamblin Class II CBTs partially surround the carotid vessels and complete resection is more challenging.

Shamblin class III CBTs intimately surround the carotid. Complete resection is very challenging, and often requires temporary interruption of the cerebral circulation for vascular reconstruction. The risk of permanent vascular and neural defects is significantly higher than for Class I and Class II tumors (26). Figure 1A–C demonstrates three Shamblin classes of CBTs.

Figure 1.

Shamblin classification. The Shamblin classification is based on involvement of the carotid arteries, which are shown by white arrows in A–C. The tumors are indicated by yellow arrows. (A) CBT (class I): the axial T2-weighted MRI shows a CBT in a typical location. Bulging of the left carotid bifurcation without any encasement of the carotid vessels. (B) CBT (class II): axial T2-weighted MRI showing a right-sided CBT with a partial encasement of the internal and external carotid artery. (C) CBT (class III): an axial slice of CT-angiography reveals a huge left-sided CBT with a complete encasement of the carotid vessels. In this case, bone destruction of the skull base, attributed to the enormous CBT, was also detected by CT (not shown).

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CT is almost crucial to evaluate temporal paragangliomas. The extent of temporal bone destruction is used to classify these tumors according to the Fisch classification (Table 1) (27).

Current genetic classification is still incomplete and merits revision. To date, nine different susceptibility genes have been identified for tumors of the paraganglial system. The six relevant genes and associated syndromes are summarized in Table 3. It is important to note that some genes are frequently, and others rarely, mutated. The succinate dehydrogenase subunit D (SDHD) gene was first recognized as the susceptibility gene of paraganglioma syndrome type 1 (PGL 1) in 2000 (28). Subsequently, mutations of the B and C subunit genes (SDHB and SDHC) were described in patients with paraganglioma syndromes that were later designated as PGL type 3 and type 4 (29),(30). The susceptibility gene for PGL 2 was identified nine years later (22). The SDHAF2 gene, also called SDH5, affects flavination of SDHA. In 2010, the SDHA gene was identified as a tumor suppressor gene associated with paraganglial tumors (31). Also in 2010, a gene called TMEM127 was found to be mutated in pheochromocytomas, i.e. exclusively adrenal paraganglial tumors (32). Meanwhile, it became evident that the spectrum of TMEM127 mutations extends to HNPs (33). Rarely, mutations of the well-known genes causing multiple endocrine neoplasia type 2 (MEN2), von Hippel-Lindau disease, and neurofibromatosis type 1 (VHL, RET, and NF1) may also predispose to HNPs.

The molecular pathomechanisms leading to the development of paraganglial tumors is still largely unknown. Various processes, including activation of hypoxia-inducible factor 1a (HIF1a)-related neoangiogenesis pathways (in von Hippel-Lindau and in SDHx-associated paraganglioma syndromes), as well as activation of the Ras oncogene pathways (in MEN2 and neurofibromatosis type 1) have been suggested. However, in HNP, the major pathomechanism may stem from the impaired function of mitochondria, manifesting either as activation of the pseudo-hypoxia pathway as a result of accumulation of succinate (which inhibits HIF-alpha prolyl hydroxylases; PHD), leading to stabilization and activation of HIF-1a (34) or as increased oxidative stress and genomic instability (35),(36). Systematic evaluation of genes involved in regulation of these pathways may reveal additional susceptibility genes. However, mutation analysis of PHD genes in patients with pheochromocytoma/paraganglioma and renal cell carcinoma showed no alterations (30).

The likelihood of identifying germline mutations in patients with HNP has been addressed by several studies. Our study, published in 2009 (37), with 598 patients with HNP, found SDHx germline mutations in 31% of patients (52% SDHD, 34% SDHB, and 14% SDHC). Predictors for a positive mutation test included family history, previous adrenal or extra-adrenal pheochromocytoma, multiple HNPs, age ≤40 years and male gender. The prevalence of germline mutations of the VHL, RET, and NF1 genes among patients with HNP has also been evaluated by our group through extensive collaboration (38). Twelve patients were found to have hereditary non-SDHx HNPs out of a total of 809 patients with HNP and 2084 with VHL: 11 with germline VHL mutations and one with a RET mutation. The prevalence of hereditary HNP was 5 out of 1,000 in patients with VHL and nine out of 1,000 in patients with non-SDHx HNP. A comprehensive literature review revealed HNPs in five von Hippel-Lindau, two MEN2 and one neurofibromatosis type 1 patients, who previously had symptoms characteristic for von Hippel-Lindau disease, MEN2 or neurofibromatosis type 1. Thus far, the number of cases associated with mutations in SDHA gene is unknown.

This issue could be addressed from the other end, i.e. the prevalence of HNPs in carriers of SDHB and SDHD mutations. This has been recently investigated by a group from Birmingham in the UK (39), who compared the penetrance for HNP for mutation carriers of SDHB and SDHD, and showed that the penetrance for SDHD was about twice as high as that of SDHB carriers. SDHD mutations induced HNPs about 20 years earlier compared with SDHB mutations.

A thorough genotype–phenotype study for different HNP loci is currently lacking in the literature. What we currently know is that patients with mutations of SDHB, SDHC, and SDHD genes may develop tumors in the carotid body and the vagal, jugular, and tympanic paraganglia (23),(28). Patients with germline mutations of the SDHAF2 gene have been studied in detail by a Dutch and Spanish group in 2010 (40). So far, only a single mutation has been identified, and potentially all patients are relatives. CBTs have been shown in a patient with a TMEM127 germline mutation (33). More patients and details may be expected in forthcoming similar reports.

Skull base paragangliomas are rare tumors, even in major referral neurosurgical centers, and they remain challenging, due to their vascularized nature and deep intra-/extracranial location. These tumors may involve the jugular bulb, middle ear, petrous apex, clivus, carotid artery, infratemporal and posterior fossa. Despite their benign nature in the majority of cases, these tumors tend to invade adjacent structures, which may sometimes preclude complete resection of these lesions. In order to achieve a good clinical outcome, close collaboration between ear, nose, and throat (ENT) surgeons, neurosurgeons, and interventional neuroradiologists is of paramount importance.

The surgical approach is determined by the size and anatomical location of the tumor. After careful analysis of MRI and thin-section CT, the surgical approach is planned with collaborative teamwork to address all aspects of the tumor. The approach should be wide, as these tumors bleed profusely on manipulation. The possibility of severe blood loss needs to be considered in pre-operative planning. Pre-operative embolization is generally recommended, especially for larger tumors. This will allow for safer surgery as a result of less intraoperative blood loss and better visualization of the structures.

Small tumors in the jugular bulb may be removed by a transjugular approach. Other approaches include the transmastoid and combined approaches (51). The intracranial part of larger tumors is frequently best removed by an infratemporal approach.

Intraoperative neuromonitoring is mandatory and should include at least electromyography of the involved cranial nerves. For tumors with major intracranial extension, motor, sensory and auditory evoked potentials may become necessary. The anesthesiologist needs to be informed about this, and plan accordingly (no gas, no long-acting muscle relaxants). The introduction of intra-operative neuromonitoring has significantly improved postoperative outcome, particularly in sparing the facial nerve during skull-base surgery (52).

The HNPs described above have a similar histopathologic appearance. Under the microscope, two types of cells displaying typical nest-like or alveolar architectural pattern are seen. Type I cells, or chief cells, are epitheloid cells often with enlarged hyperchromatic nuclei and arranged in solid groups called “Zellballen”. These groups of chief cells are surrounded by a flattened layer of type II cells or sustentacular cells, which can be visualized by immunohistochemical staining for S-100 protein (Figure 3). Type I and type II cells characteristically lie within a dense network of capillaries.

Figure 3.

Histology and immunostaining of head and neck paragangliomas. (A) Demonstration of sustentacular cells by S-100 protein in an HNP. The delicate net of sustentacular cells is surrounding the so-called Zellballen of chief cells (x200). (B) Complete immunohistochemical negativity for SDHB strongly suggesting a SDHB germline mutation (x200). (C) Immunohistochemical demonstration of SDHB protein in tumor cells, virtually excluding a germline mutation in SDHB (x200).

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Chief cells may be quite uniform or may display pronounced nuclear pleomorphism, such as bizarre and huge multinucleated cells. They are immunohistochemically positive for chromogranins (HNP shows strong expression of chromogranin B, whereas chromogranin A is expressed to a much lesser degree (53) and synaptophysin, yet are negative to cytokeratin, in contrast to some pheochromocytomas and paragangliomas of the filum terminale. Unfortunately, nuclear pleomorphism, mitotic activity, necrosis, or vascular or perineural invasion cannot predict the biological behavior, as all these features may also be found in benign HNPs.

Several attempts have been made to histologically distinguish benign tumors from the rare malignant paraganglial tumors. These are based on scoring systems that have been introduced for pheochromocytomas and paragangliomas of the retroperitoneum, although no scoring system has been generally accepted as yet. The most popular scoring system has been suggested by Thompson (54), and includes a variety of criteria, such as cellular and nuclear features, growth patterns, or occurrence of necrosis. It has to be emphasized that only the occurrence of lymph node and/or distant metastases are the ultimate criteria for malignancy. Morphologic demonstration of tumor invasion to adjacent structures including bone does not indicate biologic malignancy. Isolated tumor nodules in the vicinity of the main tumor may represent multicentricity of the HNP. Such tumor nodules can only be interpreted as lymph node metastases if they are embedded into (remnants of) lymphatic tissue.

Immunochemical staining with antibodies against SDHB protein has been found to be associated with germline mutations of the SDHB, SDHC, and SDHD genes (Figures 3A and B) (55). As a result, immunostaining has become a screening method to select patients for subsequent molecular genetic testing. The value of immunostaining against SDHB and other proteins is currently under investigation, and the importance for routine histopathology and genetics will be corroborated in expected additional analyses (56).

Management of head and neck paragangliomas is challenging for every physician, especially in cases of multiple paragangliomas or tumors in an advanced stage. The outcome mainly depends on the stage of tumor at initial presentation.

For Shamblin type I and type II CBTs, the peri- and postoperative risk of neurovascular complications is low (57). Complication rate increases strongly for Shamblin type III CBTs (57),(58). The current literature shows serious postoperative complications only in 0–2.3% of patients with Shamblin type I and II tumors, while this figure increases to 7–35.7% for patients with a Shamblin type III tumor (57–59).

For JP, surgical control is achieved in about 70–86% of patients, even in Fisch class C and D tumors (45),(60–62). Although postoperative functional deficit of the cranial nerves occurs, patients seem to be able to cope with the new limitations within two years and get back to a normal social life (60). While total resection of the tumors should be performed as a curative treatment for paragangliomas (62),(63), a subtotal removal may be required to preserve cranial nerve function. In such cases, subtotal tumor resection, combined with gamma-knife surgery or radiation therapy, has proved to be a safe and effective treatment modality (61),(64–66). In the elderly, it is important to weigh up the possible disabilities after surgical therapy, so a more conservative treatment concept might be preferred (61),(67). The outcome after surgical removal of TP (Fisch type A) is normally very good, with preservation of hearing in more than 90% of cases (63),(68–70); therefore, surgical resection of these tumors is the therapy of choice (63),(68),(70).

VPs are special. They originate from the vagus nerve, so surgical removal of these tumors will be associated with a loss of vagal nerve function in the vast majority of cases (39),(71),(72) despite the fact that the nerve is kept anatomically intact (72). The immediate consequences would be hoarseness, dysphagia, and aspiration. The situation is even worse for extensive VPs, where additional cranial nerve deficits (in about 50–60% of patients) are seen because of the close proximity of the tumor in the jugular foramen to cranial nerves IX, XI, and XII (39),(71),(72). Bradshaw and Jansen described a group of 40 patients with VPs, in whom a wait-and-scan policy was chosen (39). Only three of these patients developed cranial nerve palsy during an average follow-up of 8.5 years. It should be kept in mind that the morbidity of a cranial nerve palsy caused by surgery is higher than the morbidity caused by slow fading of the nerve function through the tumor (72). Hence, surgical removal of VPs should be weighed against the patient's age, size of the tumor, predicted tumor growth and cranial nerve function (72).