Cutaneous infections (e.g., syphilis, leprosy, herpes) and many inflammatory conditions (atopic dermatitis, pityriasis lichenoides chronica (PLC), psoriasis, lichen striatus, and lichen sclerosus) can induce post-inflammatory hypopigmentation [25] (Figs. 7.6 and 7.7). Atopic dermatitis can show pigmentary changes, which can be particularly severe if high-potency corticosteroids are used [57]. In addition, cutaneous injuries from dermatologic procedures (such as laser therapy or cryotherapy), irritants (chemical peel), or burns can also lead to the same result [58]. The pathogenesis is not well understood as the melanocytes can react with normal, increased, or decreased melanin synthesis to the insult. Although post-inflammatory hypopigmentation depends on the duration, type, and severity of insult, there is definite predisposition of individuals to hypo- or hyperpigmentation, reflected by the concept of “individual chromatic tendency” where patients with “weak” melanocytes tend to develop hypopigmentation after inflammation whereas patients with “strong” melanocytes hyperpigmentation [25]; these outcomes are considered genetically determined and inherited in an autosomal-dominant pattern. Cutaneous inflammation may cause the release of multiple mediators, which can cause aberration of melanogenesis. It has been suggested that several factors play a role in the production of post-inflammatory hypopigmentation including defect in transfer of melanosomes to keratinocytes, melanocyte loss, and decreased/inhibited melanin production [25, 56, 58]. An example of the complexity of post-inflammatory hypopigmentation is found in lichen sclerosus, a disorder characterized clinically by cutaneous hypopigmentation of the anogenital area, particularly the vulva [22, 56] (Figs. 7.6 and 7.7). Several mechanisms, alone or in combination, likely play a role in lichen sclerosus’s leukoderma: (1) decreased melanin production, (2) block in transfer of melanosomes to keratinocytes, and (3) melanocyte loss [56]. Absence of melanocytes also characterizes vitiligo, an autoimmune inflammatory disorder frequently associated with lichen sclerosus (LS). This association may be the pathogenic connection (lichenoid dermatitis triggering an autoimmune reaction to melanocytes) that underlies the clinical association of LS with vitiligo [56].

Most cases with minimal hypopigmentation improve spontaneously within weeks or months if the primary cause ceases [58]. However, in patients with severe post-inflammatory hypopigmentation, the condition can be permanent if there is complete destruction of the melanocytes.

Histologic sections show decreased to absent melanin in the basal keratinocytes, melanophages in the upper dermis, and a sparse superficial lymphohistiocytic infiltrate. Sometimes the causative inflammatory condition such as lichen sclerosus may also be evident (Figs. 7.6 and 7.7). Fontana-Masson or Warthin-Starry histochemistry can help document the decreased melanin content of basal keratinocytes and none or only rare dendritic melanocytes within the epidermis. Similarly, immunohistochemical melanocytic markers (microphthalmia-associated transcription factor (MITF), HMB-45, and melanoma antigen recognized by T-cells 1 (Mart1) may show a decreased number or regional loss of melanocytes (Figs. 7.6 and 7.7).

The clinical differential diagnosis includes sarcoidosis [59], lichen sclerosus [56], hypopigmented mycosis fungoides, hypopigmented extramammary Paget’s disease [60], hypopigmentation after high-potency topical corticosteroid usage, vitiligo, and chemical leukoderma [58]. Histologic examination and clinicopathologic correlation can easily differentiate these entities. In particular sarcoidosis shows noncaseating granulomas; mycosis fungoides, a lichenoid infiltrate of atypical lymphocytes with epidermotropism; extramammary Paget’s disease exhibits large atypical epithelioid cells within the epidermis; vitiligo, absence of melanocytes; and chemical leukoderma, a reduction of melanocytes. Nevertheless, even if the biopsy is not conclusive, the exclusion of some of the entities in the differential diagnosis is useful for diagnostic classification and management.

Vitiligo, an acquired leukoderma, is one of the most frequent disorders of pigmentation of the skin and is characterized by distinct areas of skin and mucous membranes depigmentation. It affects up to 2 % of the population, tends to be progressive, and is more common between the ages of 10 and 30 years with no predilection for either sex or ethnic origin. The genitalia are one of the most commonly affected areas along with the face, neck, body creases, scalp, and axillae [61]. Vitiligo can be divided in four subtypes, referred to as generalized, segmental or localized, universal, and acrofacial. The generalized type tends to be symmetric, whereas the localized form, which can follow a mosaic distribution, is more common in children and more difficult to treat [62, 63]. The Koebner phenomenon, where trauma triggers the development of vitiligo, is a common phenomenon in the generalized type [64].

A family history exists in 30 % of the patients. Vitiligo is considered to have primarily an autoimmune etiology [65, 66] as it is commonly associated with other diseases of autoimmune etiology such as Hashimoto’s thyroiditis, pernicious anemia, psoriasis, and lichen sclerosus [61]. The presence of anti-melanocyte antibodies supports the immune theory as an effector of melanocytic destruction. Patients with generalized form are more likely to have a concomitant autoimmune disease, whereas it is less frequent in patients with the localized, segmental (mosaic) form. Other theories implicate neural and cytotoxic factors, oxidant and antioxidant reactions, and alterations in melanocyte function in the pathogenesis of vitiligo; however, these mechanisms are not mutually exclusive and may exist in varied combinations [61].

On clinical examination, vitiliginous skin shows hypo- or depigmented macules and patches, sometimes with repigmentation that is frequently incomplete and ephemeral (Fig. 7.6). Ivory-white patches of skin with erythematous borders herald the initial stages and may indicate an ongoing inflammatory process. While hairs growing in patches of vitiligo are white, melanocytes sometimes remain in the hair follicles, resulting in tiny, annular rims of normally pigmented skin within the area of vitiligo. As vitiligo patients regain their pigmentation, the repigmentation process is believed to originate from these residual follicular (stem cell) melanocytes. Examination with the Wood’s light can greatly assist in revealing areas of hypo- and depigmentation [67]. Depigmented areas are brightly white in comparison to the subdued reflections of the hypopigmented areas by Wood’s light.

Vulvar skin affected by end-stage vitiligo is completely devoid of melanin within the basal keratinocytes, and melanocytes are entirely absent along the epidermal side of the basement membrane zone (Fig. 7.6). The ideal biopsy is taken through the edge of a lesion so that the vitiligo macule/patch can be compared with the adjacent normal skin. The edge of the vitiligo lesion may show a narrow zone of degenerating basal melanocytes and a lymphocytic infiltrate in the underlying papillary dermis and lower dermis hinting at the possibility that a local immune reaction is responsible for the melanocyte loss [65, 68]. Fontana-Masson or Warthin-Starry stain for melanin and immunohistochemical studies with various melanocytic markers such as S-100 protein, Mart1/MelanA, MITF-1, and HMB-45 are helpful in highlighting the differences in melanin content as well as the presence and density of melanocytes between normal and lesional skin samples (Fig. 7.6). In early vitiligo, some persistent melanocytes may be found, correlating with the clinically observed hypopigmentation instead of depigmentation. Since Langerhans cells are usually increased in vitiliginous skin, utilization of melanin/melanocyte-specific immunohistochemistry markers is recommended rather than the sensitive but nonspecific melanocyte marker S-100 protein, which could produce false-positive results [69].

In difficult cases, the differential diagnosis includes idiopathic guttate melanosis, tinea versicolor, post-inflammatory hypopigmentation, halo nevi, and regressing melanoma [61]. Histologically idiopathic guttate melanosis shows a decrease in melanin pigment and the number of melanocytes but never a complete absence of them; tinea versicolor, a fungal infection caused by Malassezia furfur, will demonstrate spores and hyphae within the stratum corneum; in post-inflammatory hyperpigmentation, melanophages in the upper dermis and a sparse superficial lymphohistiocytic infiltrate will be evident; halo nevi will show nevus cells in a dense lymphocytic infiltrate; and in regressing melanoma, areas of loose fibrosis, dilated vessels, lymphocytes, and melanophages will be noted adjacent to a malignant melanoma. In general none of the above entities will show a complete absence of melanocytes as seen in vitiligo. Sometimes in cases of depigmentation, it may be difficult to differentiate vitiligo from lichen sclerosus (Fig. 7.7). Both are autoimmune disorders and sometimes coexist in the same patient. However, vitiligo shows macular loss of pigment, whereas lichen sclerosus shows indurated, elevated white papules and plaques due to its hallmark sclerotic alteration of the dermis.

Vulvar nevi are relatively uncommon, occurring in up to 2.3 % of women presenting with pigmented vulvar lesions [3–5]. In children, the prevalence of genital nevi is 3.5 %, with a male to female ratio of 1.3:1 [70]. Acquired nevi appear in early childhood and continue to develop into early adulthood. They can occur in modified mucous membranes or keratinized skin and virtually all are acquired [4, 70]. Usually they are solitary but occasionally can be multiple. In a consecutive series of 59 vulvar nevi, 12 % were junctional, 36 % compound, and 52 % intradermal [71]. Typically, common vulvar nevi are small in size (<7 mm), symmetric with regular borders, and uniformly tan to brown in color (Fig. 7.8). Rarely, they can have a bluish appearance due to dermal pigment. Vulvar nevi can be flat-topped, dome-shaped, or macular [7]. Nevi that vary from these characterizations require biopsy [9]. These deviations may well represent atypical vulvar melanocytic nevi, but melanoma must be excluded.

In general, on histologic examination, common vulvar melanocytic nevi display the same banal morphology without any cytologic atypia or unusual architectural patterns, indistinguishable from that of common nevi in other parts of the body [71] (Figs. 7.9, 7.10, and 7.11). Junctional melanocytic nevi are characterized by a proliferation of benign-appearing nevoid melanocytes arranged in solitary units and nests along the basement membrane zone of the epidermis with well-defined lateral margins and symmetric distribution. Although pure vulvar junctional melanocytic nevi are less frequently encountered under the microscope compared to compound and intradermal melanocytic nevi, the proportion of these three subtypes of common melanocytic nevi in the vulva does not differ significantly from the torso [71]. In compound melanocytic nevi, nests of benign-appearing nevoid melanocytes are present in the dermis in conjunction with an epidermal component. The dermal melanocytes usually do not display discernible pigmentation, although in rare cases, heavy pigmentation may be present focally in some superficial dermal nests. In addition to the absence of cytologic atypia and conspicuous mitotic activity, the dermal component demonstrates zonal maturation as the melanocytes become smaller and more spindled (instead of epithelioid) and lose cytoplasmic pigment (in cases with superficial heavy pigmentation) with descent into the deep dermis/submucosa. In intradermal melanocytic nevi, the melanocytes, depending on their extent into the dermis or submucosa, exhibit zonal maturation varying from junctional type A (epithelioid) melanocytes to superficial dermal type B (nevoid) melanocytes and deep dermal type C (spindle/neurotized) melanocytes. In contrast to atypical genital melanocytic nevi or dysplastic nevi, common vulvar nevi do not exhibit any architectural distortion or cytologically atypia.

Clinically, vulvar melanocytic nevi can sometimes be difficult to differentiate from seborrheic keratosis, warts, pigmented vulvar intraepithelial neoplasia (VIN), or angiokeratomas; however, a biopsy can distinguish these entities from a vulvar melanocytic nevus without difficulty. Vulvar melanosis and lentigo simplex per definition do not show any melanocytic nests; the former shows an increase in dendritic melanocytes while the latter is associated with an increase in solitary, nevoid melanocytes along the sides of elongated, pigmented rete ridges. Nevoid melanoma of the anogenital region is rare but can be recognized by worrisome features such as deep dermal mitotic figures, absence of maturation, and subtle cytologic atypia [72, 73]. See Vignette 3 at the end of this chapter.

Blue nevus, common or cellular subtype, is very rare in the vulva but has been reported in a handful of cases [74–77]. Vulvar blue nevi are believed to arise from Schwann cells of stromal nerves/perineural precursor cells or from latent dendritic melanocytes which have migrated from the neural crest [17, 78] or from mutated precursor stem cells [79]. Clinically, it is gray blue in color, which has been attributed to the scattering of light by dermal collagen and transmission of the blue wavelengths (Tyndall effect).

The common blue nevus is composed of varied populations of heavily pigmented bipolar dendritic melanocytes and nonpigmented spindle cells within the dermis. The hallmark cells of blue nevus are the dendritic melanocytes, which are characterized by elongated, slender dendrites with cytoplasm containing variable but usually quite prominent, fine melanin granules (Figs. 7.12 and 7.13). They do not exhibit any pleomorphism and are located between dermal collagen bundles, which may appear slightly thickened. Melanophages are usually conspicuous but mitoses are absent. Of note, in a typical case of blue nevus, no melanocytic proliferation is identified in the overlying epidermis or epithelium.

The cellular blue nevus is composed of spindle-type melanocytes that form a bulky nodule within the dermis, which commonly extends into the subcutaneous tissue in a characteristic dumbbell appearance. Typically, cellular blue nevus displays a biphasic pattern with clusters of clear, relatively light to nonpigmented spindle cells admixed with heavily pigmented spindle melanocytes. The tumor grows in an alveolar pattern with interspersed giant cells. Mitotic figures are sparse to absent. The spindle melanocytes may locally infiltrate superficial peripheral nerves and subcutaneous tissue, histologic features that should not be interpreted as malignancy [80]. A component of common blue nevus is frequently present at the periphery of the cellular nodule, whose recognition may facilitate the diagnosis of cellular blue nevus.

Another variant of blue nevus that can occur in genital mucosa is the epithelioid blue nevus [81]. This variant has been described mostly in patients with the Carney complex, but they may occur in isolation. Its pathognomonic features are polygonal epithelioid melanocytes situated within the dermis/submucosa that show no maturation with progressive depth of dermal infiltration. In contrast with the usual stromal changes in common blue nevi, epithelioid blue nevi exhibit no dermal fibrosis. In the genital region, no recurrence or metastasis has been reported and simple excision has been curative. However, epithelioid blue nevus is also known as pigmented epithelioid melanocytoma, which is a recently proposed term that encompasses melanocytic proliferations diagnosed as “animal-type melanoma” or “pigment-synthesizing melanoma.” This variant of melanocytic tumors is considered a low-grade melanocytic proliferation that can give rise to locoregional lymph node metastases and rarely to distant metastases [82, 83].

Lastly, atypical cellular blue nevus is an exceedingly rare variant of cellular blue nevus, which exhibits a combination of architectural atypia (deeply infiltrative border and/or asymmetry) or cytologic atypia (focal nuclear pleomorphism and hyperchromatism, bizarre cells, and increased mitotic activity). Although the atypical histologic and cytologic features of atypical cellular blue nevus are worrisome for a malignant melanocytic lesion, there are subtle clinical and morphologic differences between atypical cellular blue nevus and malignant blue nevus, its malignant counterpart [80]. However, there is a significant disagreement between experienced dermatopathologists in the diagnosis of atypical cellular blue nevus due to a lack of strict clinical and morphologic criteria for this variant of cellular blue nevus [84]. Of note, atypical cellular blue nevus has never been reported in the vulva [80]; however, malignant blue nevus has occurred in vulva [76]. Mitotic figures and significant cytologic atypia differentiate malignant blue nevus form atypical blue nevus [80].