Management of Cutaneous Head and Neck Melanoma


Key Points

  • The incidence of melanoma continues to increase at epidemic proportions.

  • Warning signs for melanoma include lesion asymmetry, border irregularity, color variation, diameter greater than 6 mm, and evolving changes. A subset of cancers—such as nodular, amelanotic, and desmoplastic melanoma—lack these features.

  • Any pigmented lesion that meets these criteria, has undergone change, or appears different from surrounding nevi warrants biopsy. Prognostic information from this biopsy guides treatment, which entails wide local excision using 0.5- to 2-cm margins and possible sentinel lymph node biopsy (SLNB).

  • The American Joint Committee on Cancer (AJCC) staging system for cutaneous melanoma is founded on the traditional tumor-node-metastasis (TNM) classification. Nodal status is the single most important prognostic factor for melanoma patients.

  • The T classification is defined by tumor thickness and ulceration. Ulceration of the primary lesion upstages the patient regardless of Breslow depth. Mitotic rate remains a prognostic factor and should be documented, but it is no longer incorporated into the latest AJCC staging system due to the substratification of T1 tumors.

  • Significant prognostic factors with stage III regional disease include number of lymph nodes and tumor burden (microscopic vs macroscopic disease). Satellite and in-transit metastases are important prognostic features; they are classified as stage III (N1c) regional disease regardless of the nodal status.

  • The M classification is defined by anatomic site of distant metastasis and elevated lactate dehydrogenase (LDH) level.

  • The standard of care for melanoma treatment remains complete surgical excision of the primary lesion. Therapeutic lymph node dissection (TLND) is universally accepted as the treatment for proven regional disease in the neck. Prophylactic elective neck dissection for the N-zero neck failed to demonstrate an overall survival benefit and has been replaced by SLNB.

  • Interferon-α2b is no longer the only adjuvant treatment for stage III disease approved by the FDA. It is reserved for patients at high risk for recurrence (i.e., individuals with regional metastasis or a primary lesion measuring more than 4 mm in thickness).

  • Radiation is an adjuvant therapy for high-risk patients with extracapsular spread or multiple node involvement.

  • Dacarbazine (DTIC), IL-2, ipilimumab, vemurafenib (for BRAF -mutated tumors) and PD1 inhibitors (nivolumab; pembrolizumab) are approved for treatment of advanced stage IV melanoma.

Introduction

Although the overall trend in the United States demonstrates a stabilization of cancer incidence and a decrease in cancer death rates, the incidence of cutaneous melanoma continues to rise. In 1935 the lifetime risk for developing melanoma was 1 in 1500 individuals. By 2015, an estimated 1 in 50 Americans were diagnosed with invasive melanoma during their lifetimes. Today the lifetime risk for a man developing melanoma is 1 in 27 and for a woman 1 in 42. In addition, 4% of all adolescent cancers are attributed to melanoma.

A recent systematic review of the literature estimated the total direct cost of treating Medicare patients with existing melanoma to be $44.9 million, whereas newly diagnosed cases soared to $932.5 million. Fortunately the management of cutaneous melanoma is also one of fastest evolving fields in cancer, with promising research taking place at both the molecular and clinical levels. Given its association with sun exposure, melanoma is considered a preventable disease. Decreased incidence and mortality ultimately hinges on increased education, prevention, early diagnosis, and improved treatment for advanced disease.

Epidemiology

The American Cancer Society estimates that there were 91,270 new cases of invasive melanoma in the United States in 2018 and an additional 87,290 cases of melanoma in situ. Since 2004, the annual percentage change in melanoma incidence among Caucasians has increased steadily by 3% each year. Melanoma remains the most lethal form of skin cancer, accounting for an estimated 9320 American deaths in 2018. This estimate averages to approximately one American dying from melanoma every hour. Over the past 50 years, the annual percentage change in mortality rate has increased steadily at 1.8% per year.

Approximately 25% of all cutaneous melanomas arise in the head and neck (HN) region, with the majority involving the cheek, scalp, and neck. A slight male predominance is consistently reported, and the median age of diagnosis is 59 years. However, juvenile cases account for 1.66% of HN melanoma cases, with patients as young as 4 years of age being diagnosed. Overall, 1 in 4 patients are diagnosed before the age of 40 years, and it is the most common form of cancer in patients 25 to 29 years of age. Consequently melanoma represents one of the leading cancer causes of lost potential life years, with 20.4 years lost to melanoma compared with 16.6 years attributed to all other cancers.

Etiology and Risk Factors

Numerous environmental and genetic risk factors have been implicated in the development of cutaneous melanoma. These are summarized in Box 80.1 .

Box 80.1
Modified from Schmalbach CE: The management of head and neck melanoma, Curr Probl Surg 43:781, 2006.
Risk Factors Associated With Cutaneous Melanoma

Environmental/Sun Exposure

  • Inability to tan

    • Fair complexion

    • Blue/green eyes

    • Blond/red hair

    • Freckling

  • History of blistering or peeling sunburns

  • Immunosuppression

  • Teenage outdoor summer jobs

  • Tanning booth exposure

Genetic/Medical History

  • CDKN2A (p16) mutation

  • Family history of melanoma

  • History of prior melanoma

  • Actinic keratoses

  • Nonmelanoma skin cancer

  • Xeroderma pigmentosa

  • Atypical (dysplastic) nevus

  • Giant congenital melanocytic nevus

Risk Factors

Sun exposure is considered the leading cause of melanoma. Patients who experienced peeling or blistering sunburns, even during childhood, are at particular risk. Sun beds and tanning booths are associated with early-onset melanoma; increasing risk is associated with both early age of first use as well as with greater use. First use of a tanning bed before age 35 years alarmingly increases the risk for melanoma by up to 75%. The World Health Organization (WHO) now classifies tanning booths as a category I carcinogen. In fact, the risk of developing melanoma from tanning booth exposure exceeds the risk of developing lung cancer from cigarette smoking. Other associated factors include blond or red hair, green or blue eyes, or fair skin consistent with Fitzpatrick skin types I through III. Adults with more than 100 clinically normal-appearing nevi, children with more than 50 clinically normal-appearing nevi, and any patients with atypical or dysplastic nevi are also at risk. A prior history of melanoma places a patient at increased risk, with 5% to 10% of individuals developing a second primary melanoma.

Genetics

The genetic aspect of melanoma remains complex, with over 33,000 mutations identified. An inherited chromosomal abnormality at the CDKN2A locus, which encodes for the p16 tumor suppression gene, is the most common germline mutation. A point mutation in the serine-threonine protein kinase BRAF is present in approximately 42% of melanomas, the majority being the V600E substitution. Additional melanoma mutations include NRAS (25% of tumors) and c-KIT (19%).

Some 10% to 15% of melanoma patients report a positive family history. Xeroderma pigmentosum (XP) is a rare hereditary disorder that is also associated with melanoma; it is inherited in an autosomal recessive fashion. The fibroblasts in XP patients have a reduced or absent ability to repair DNA damaged by ultraviolet light. B-K mole syndrome is a hereditary form in which individuals acquire large, irregular, dysplastic nevi, often in sun-protected regions of the body, such as the scalp and trunk. A familial association of melanoma among individuals with atypical nevi has also been coined familial atypical multiple mole-melanoma (FAMMM) syndrome. Today the term atypical mole syndrome is applied to familial cases of melanoma. The syndrome is inherited in an autosomal dominant fashion.

Congenital Nevi

Congenital melanocytic nevi (CMNs) are present at birth or appear within the first 6 months of life ; an estimated 1% to 6% of children are born with CMN. The nevi are classified by their adult size: small CMNs are less than 1.5 cm in diameter and account for the majority of lesions; medium CMNs measure between 1.5 and 19.9 cm in diameter; and large CMNs, which are also called giant congenital nevi , measure 20 cm or more. This large size can have significant cosmetic and psychosocial implications.

The lifetime risk of melanoma development in small- and medium-sized CMNs is estimated to be between 0% and 4.9%. Routine prophylactic removal of small- and medium-sized CMNs is rarely indicated in the absence of signs or symptoms indicative of malignant progression. However, giant congenital nevi carry a higher risk for melanoma, with an estimated 4.5% to 10% of patients going on to develop cancer. Seventy percent of these individuals are diagnosed before the age of 10 years. Melanoma in the setting of giant congenital nevi may develop below the dermoepidermal junction, which makes identification more difficult and delays diagnosis.

Classification of Melanoma

It is important to note that melanoma subtype does not generally influence prognosis after correcting for other prognostic variables such as tumor thickness and ulceration. Superficial spreading melanoma is the most common type of cutaneous melanoma, accounting for approximately 70% of all cases. It commonly arises in the setting of a preexisting nevus, with a diagnosis rendered during the fourth or fifth decade. Nodular melanoma is the second most common subtype on the skin, accounting for 15% to 30% of cases. This lesion typically appears as a blue-black or blue-red nodule. For this reason, a nodular melanoma must be differentiated from a hemangioma, blue nevus, pyogenic granuloma, and pigmented basal cell carcinoma.

Lentigo maligna (LM) represents intraepidermal or in situ melanoma. Histologically it is often seen in the background of chronic sun damage. LM is the precursor to invasive lentigo malignant melanoma (LMM). The exact percentage of LMs that progress to invasive LMM remains unknown ; however, it is speculated that if patients live long enough, all LMs will eventually progress to invasive melanoma. LM/LMM is most often found in the HN region. Traditionally, the subtype has been associated with older individuals, but the frequency in younger patients is increasing. The LM/LMM pattern warrants special comment, because this subtype is characterized by asymmetric, subclinical, and often extensive peripheral involvement of atypical junctional melanocytic hyperplasia (AJMH). Therefore management with adequate wide margins can be challenging from both the functional and cosmetic standpoints. Additionally, amelanotic and invasive desmoplastic melanomas (DMs) (see later) often arise within LM/LMM.

Desmoplastic Melanoma

DM is rare, accounting for less than 4% of all cutaneous melanomas. However, up to 51% of the lesions present in the HN region and may arise in association with LM/LMM. The clinical presentation and biologic behavior of these tumors are distinct from those of other cutaneous melanomas. Although amelanotic cases account for only 4% to 5% of cutaneous melanomas, up to 73% of DMs are amelanotic. As demonstrated in Fig. 80.1 , the neoplasms often lack the typical ABCD criteria for melanoma (described later) and can have a difficult histologic pattern that requires interpretation by an experienced pathologist. Overall, the atypical and challenging appearance of DMs may result in a delay in diagnosis and thicker Breslow depth at diagnosis.

Fig. 80.1, Desmoplastic melanoma of the nose. Note the amelanotic appearance and absence of typical ABCD findings (such as a symmetry, b order irregularity, c olor variation, and d iameter greater than 6 mm) associated with other melanoma subtypes.

DM is known to be locally aggressive and highly infiltrative, often leading to cranial nerve and skull base involvement. Local recurrence has been reported in up to 50% of cases. Explanations for this high rate include the association with neurotropism and the failure to recognize and adequately clear peripheral AJMH margins. Although DM demonstrates greater tumor thickness at the time of diagnosis, there is a lower risk of regional lymph node metastasis for the “pure” desmoplastic pattern compared with the mixed desmoplastic pattern, which behaves similar to conventional melanoma subtypes. The incidence of nodal metastasis found by SLNB has been reported as low as 1% for purely DM; however, the rate of cervical lymph node metastasis can reach as high as 22% in the setting mixed DM. For this reason, SLNB is used primarily in the setting of mixed DM, not pure DM. This difference in metastatic rate highlights the need for accurate and complete histopathologic evaluation of the primary tumor for development of a treatment plan.

Unknown Primary

Approximately 2% to 8% of melanoma cases involve unknown primary sites. Two-thirds of these patients present with regional metastasis in the absence of an identifiable primary lesion or history of melanoma; the remaining third of such cases involve distant metastasis to sites such as the subcutaneous tissues, lung, and brain.

Patients diagnosed with melanoma of unknown origin require a search for the primary site with a total body skin and mucosal evaluation. A history of a previous skin biopsy or skin lesion that spontaneously disappeared may be helpful. All pathology slides from previously excised lesions should again be reviewed. The workup for metastasis is identical to that for known primary cases, as described further on. After adjustment for tumor stage, melanomas of unknown primary origin share an overall prognosis equivalent to that of their counterparts with known primary sites.

Diagnostic Workup

History

The majority of melanoma lesions are first detected by the patient or the patient's significant other. Less than one-fourth of lesions are diagnosed during routine office physical examination; when found by a health care provider, however, lesions tend to be thinner. Overall, 80% of newly diagnosed melanomas will be limited to localized stage I/II disease.

The earliest signs of melanoma are a change in the color, size, or shape of a lesion. Pruritus is the earliest symptom. Later signs and symptoms, which are usually associated with a more advanced lesion, include bleeding, ulceration, and tenderness. Patients should be questioned about a personal and family history of melanoma. Information about previous skin biopsies, sun exposure, history of blistering sunburns, tanning booth use, chronic sun exposure, and occupation should be obtained. Johnson and colleagues investigated the characteristics of 1515 melanoma patients and found that 81% reported a history of at least one sunburn.

Physical Examination

All patients presenting with a suspicious lesion warrant full evaluation of the skin and nodal basins by a physician who is well versed in cutaneous cancers. Thorough evaluation is imperative, because up to 8% of newly diagnosed patients will have multiple primary cutaneous melanomas. The differential diagnosis for cutaneous melanoma is broad and includes seborrheic keratosis, hemangioma, blue nevus, Spitz nevus, pyogenic granuloma, pigmented basal cell carcinoma, and cutaneous squamous cell carcinoma.

The American Cancer Society has published the ABCD checklist to educate both patients and physicians about the early detection of melanoma. Under these guidelines, concerning signs for melanoma include the following:

  • A symmetry in appearance

  • B order irregularity, such as scalloped, poorly circumscribed, or ill-defined margins

  • C olor variation within a lesion, such as shades of black, red, white, or blue

  • D iameter greater than 6 mm

Although the ABCD checklist is helpful for the identification of melanoma, it will not detect every case. It is important to realize that a subset of cancers (e.g., amelanotic, desmoplastic, and nodular melanomas) lack the common features of the ABCDs. In one series, 88% melanoma patients (615 of 696) recalled change in their pigmented lesion prior to melanoma diagnosis. Due to the significance of change, a proposal has been set forth to add E —evolving changes—to the traditional ABCD warning signs. Clinicians are hopeful that the new, more comprehensive ABCDE criteria will lead to even better detection of melanoma at an earlier stage. Another useful screening tool is the “ugly duckling sign,” or any pigmented lesion that appears significantly and singularly different from other surrounding lesions. Such a lesion should be viewed with a high index of suspicion even if it lacks the traditional ABCD criteria.

Biopsy

Any pigmented lesion that demonstrates an ABCD warning sign, has undergone change, or appears different from surrounding nevi necessitates histologic evaluation. Ideally, a complete excisional biopsy with a narrow 1- to 3-mm clinical margin of surrounding skin is performed. This allows for the diagnosis and evaluation of important prognostic factors such as Breslow depth, ulceration, mitotic rate, and angiolymphatic/perineural invasion. For lesions that are not amenable to excisional biopsy due to their large size or anatomic location, punch biopsy or incisional biopsy through the thickest or darkest portion of the neoplasm is recommended. Superficial shave biopsy, frozen section biopsy, and fine-needle aspiration are strongly discouraged because the thickness of the tumor, which dictates staging and treatment, may not be accurately obtained. It is important to realize that punch and incisional biopsies are subject to sampling error. If a diagnosis of melanoma in this setting is not rendered, a repeat biopsy may be necessary. The pathology results from this biopsy then serves as the guide for treatment, which entails wide local excision (WLE) using a 0.5- to 2-cm margin of normal surrounding skin with or without SLNB. Although obtaining wider margins at the time of the initial biopsy seems efficient and cost-effective, it is highly discouraged because the removal of significant amounts of skin surrounding the lesion may compromise the ability to accurately stage regional lymph node basins using lymphoscintigraphy and SLNB techniques. Instead, excisional biopsy with narrow margins for diagnosis is advocated.

The American Academy of Dermatology (AAD) and National Comprehensive Cancer Network (NCCN) recommend standardized reporting for melanoma pathology. This information allows for accurate staging and associated treatment planning. Key components to the report include the following:

  • Tumor (Breslow) depth of invasion

  • Mitotic rate

  • Margin status

  • Ulceration, which is a histologic diagnosis

  • Melanoma subtype to include pure versus mixed desmoplasia if applicable

  • Clark level of invasion for thin melanomas measuring up to 1 mm in depth of invasion

  • Vertical growth pattern

  • Tumor-infiltrating lymphocytes (TILs)

  • Angiolymphatic invasion

  • Tumor regression

  • Neurotropism

  • Microsatellitosis

Melanoma remains a histopathologic diagnosis using traditional hematoxylin and eosin (H&E) staining and melanoma-specific immunohistochemical staining such as HMB-45, S-100, and MART-1 (Melan-A).

Advances have been made in gene profiling, including comparative genomic hybridization (CGH) and fluorescence in situ hybridization (FISH). A diagnostic reverse-transcription polymerase chain reaction assay is commercially available to assist in differentiating melanoma from benign lesions such as Spitz nevi, junctional nevi, and blue nevi (myPath Melanoma test; Myriad Genetics, Inc., Salt Lake City, UT). Gene expression profiling (GEP) is also commercially available to help stratify high- versus low-risk melanoma metastasis in stage I and II disease (DecisionDx-Melanoma; Castle Biosciences, Inc., Friendswood, TX). However, testing sensitivity and specificity remains low and rigorous validation is still required for the mentioned tests to become standard of care.

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