Open Access

Reflectance confocal microscopy and dermoscopy for in vivo, non-invasive skin imaging of superficial basal cell carcinoma

  • Authors:
    • Mihaela A. Ghita
    • Constantin Caruntu
    • Adrian E. Rosca
    • Harillaq Kaleshi
    • Ana Caruntu
    • Liliana Moraru
    • Anca Oana Docea
    • Sabina Zurac
    • Daniel Boda
    • Monica Neagu
    • Demetrios A. Spandidos
    • Aristidis M. Tsatsakis
  • View Affiliations

  • Published online on: March 21, 2016     https://doi.org/10.3892/ol.2016.4354
  • Pages: 3019-3024
  • Copyright: © Ghita et al. This is an open access article distributed under the terms of Creative Commons Attribution License.

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Abstract

Superficial basal cell carcinoma (sBCC) is the second most frequent histological type of basal cell carcinoma (BCC), usually requiring a skin biopsy to confirm the diagnosis. It usually appears on the upper trunk and shoulders as erythematous and squamous lesions. Although it has a slow growth and seldom metastasizes, early diagnosis and management are of crucial importance in preventing local invasion and subsequent disfigurement. Dermoscopy is nowadays an indispensable tool for the dermatologist when evaluating skin tumors. Reflectance confocal microscopy (RCM) is a novel imaging technique that allows the non‑invasive, in vivo quasi‑microscopic morphological and dynamic assessment of superficial skin tumors. Moreover, it offers the advantage of performing infinite repeatable determinations to monitor disease progression and non-surgical treatment for sBCC. Herein, we present three lesions of sBCC evaluated using in vivo and non‑invasive imaging techniques, emphasizing the usefulness of combining RCM with dermoscopy for increasing the diagnostic accuracy of sBCC.

Introduction

Superficial basal cell carcinoma (sBCC) is the second most frequent type after nodular basal cell carcinoma (BCC), and it typically appears on the trunk, as erythematous and squamous lesions, that can be very difficult to differentiate from other skin diseases with a similar clinical presentation. Although it usually has a slow growth and seldom metastasizes, if left untreated, sBCC lesions can produce extensive local distruction, causing significant morbidity or disfigurement. Early diagnosis and management are of crucial importance in preventing detrimental outcomes (13).

Reflectance confocal microscopy (RCM) is a novel high resolution imaging technique that allows the rapid and reproducible evaluation of sBCC in combination with dermoscopy (4), avoiding the invasiveness and high costs associated with skin biopsies. In this study, we aimed to expound the clinical usefulness of combining RCM and dermoscopy for the in vivo, non-invasive diagnosis of sBCC. For this purpose, we present three lesions of sBCC which we evaluated using in vivo and non-invasive imaging techniques.

Case reports

Case 1

A 46-year-old man, phototype III [fair to matte skin, sometimes burns, always tans (medium tan) with a few freckles], presented in March 2014 to the Dermatology Department of ‘Prof. N. Paulescu’ National Institute of Diabetes, Nutrition and Metabolic Diseases in Bucharest for the evaluation of a slow-growing lesion on his back, which he had first noticed 2 years ago. He reported significant sun exposure during his lifetime, consistent with the mottled telangiectatic and lentiginous background skin observed upon clinical examination. On his left upper back, there was a pink-colored patch with telangiectasias and ill-defined borders, measuring approximately 2.1×1 cm (Fig. 1A). Dermoscopy [all dermoscopic images in our study were captured at 10-fold magnification prior to RCM imaging using the integrated VivaScope 1500 VivaCam macro camera (Lucid Inc., Rochester, NY, USA)] revealed pink to red structureless areas with arborizing microvessels, short fine telangiectasias and few blue-gray globules (Fig. 1B). RCM examination revealed the presence of multiple, small islands of basaloid cells, connected into a multilobular, flower-like architecture by highly-reflactile, fibrous tissue in the superficial dermis (Fig. 1H). Tumor islands exhibited peripheral palisading of nuclei and were surrounded by peritumoral, dark spaces (Fig. 1E and G). At the level of the spinous layer, keratinocytes with elongated nuclei, oriented along the same axis formed the typical ‘streaming of the epidermis’ (Fig. 1D). Numerous inflammatory cells (Fig. 1F) and dilated capillaries (Fig. 1G) were also observed. A histopathological examination confirmed the diagnosis of sBCC. It was characterized by small aggregates of basaloid cells with peripheral palisading and prominent clefting in the papillary dermis, connected to the base of the epidermis (Fig. 1C).

Case 2

A 64-year-old woman, also phototype III, without any significant personal and familial medical history, presented in February 2014 with 2 slow-growing lesions to the Dermatology Department of ‘Prof. N. Paulescu’ National Institute of Diabetes, Nutrition and Metabolic Diseases in Bucharest. The first lesion, located on her right forearm, was an erythematosquamous plaque with an irregular border, measuring approximately 2.5×2.3 cm (Fig. 2A). Dermoscopy revealed pink-white structureless areas, small erosions, arborizing microvessels, superficial fine telangiectasias and brown dots (Fig. 2B). RCM of the superficial dermis identified tumor islands surrounded by peritumoral dark spaces (Fig. 2E), dark silhouettes (Fig. 2H), an erosion, increased vascularization (Fig. 2F) and bright inflammatory cells (Fig. 2G). Dark silhouettes correspond to the hypopigmented variant of tumor islands. At the level of the stratum spinosum, the presence of streaming of the epidermis was also observed (Fig. 2D). A histopathological analysis confirmed the diagnosis of sBCC. The main findings were represented by multiple small islands of basaloid cells with peripheral palisading that emanate from the undersurface of the epidermis into a loose fibromucinous stroma. Moreover, a small loss of substance covered by hematic and lymphocytic exudates could be observed within the tumor and an abundand peritumoral inflammatory infiltrate consisting of lymphocytes, histiocytes and rare melanophages (Fig. 2C).

The second lesion, located on the patient's left shoulder, was an erythematous, slightly scaly plaque with a stelate shape, measuring 2.5×2.1 cm. Telangiectasias could be observed on its surface and a brownish hue at its periphery (Fig. 3A). Dermoscopy revealed pink to red structureless areas, multiple arborizing microvessels, superficial fine telangiectasias and few brown dots (Fig. 3B). RCM revealed the presence of hyporefractile tumor islands surrounded by highly refractile fibrous stroma (Fig. 3F), tortuous, dilated capillaries with leukocyte trafficking (Fig. 3D and H) and clustered inflammatory cells (Fig. 3G). Plump cells, described as large, bright, oval cells were present within and at the periphery of the tumor islands (Fig. 3E and G). Highly refractile projections, possibly belonging to dendritic cells could also be observed (Fig. 3H). Histopathological analysis revealed islands of basaloid cells in the papillary dermis, with characteristic peripheral palisading, thus confirming the diagnosis of sBCC (Fig. 3C).

Discussion

The presented instructive case reports demonstrate the usefulness of dermoscopy and RCM for the rapid, in vivo, non-invasive evaluation of sBCC, suggesting that a combination of these two diagnostic methods may significantly reduce the number of necessary skin biopsies. This is of great importance to everyday dermatological practice, considering the invasiveness associated with biopsies, high costs and elapsed time until receiving the histopathological report and the recommended non-surgical treatments for sBCC.

Dermoscopy is nowadays indispensable for the dermatologist in the non-invasive, in vivo diagnosis of BCC (5,6) and there is a growing number of studies that describe relevant dermoscopic criteria for differentiating between BCC subtypes (4,7). Shiny white to red areas and short fine telangiectasias are considered the dermoscopic hallmarks of sBCC, with multiple small erosions as an additional dermoscopic clue for the diagnosis (8,9). Moreover, a group of investigators proposed a dermoscopic algorithm that could discriminate sBCC from other BCC subtypes with a sensitivity of 81.9% and a specificity of 81.1% (7). In the cases presented herein, dermoscopic images were captured at 10-fold magnification prior to RCM imaging. Dermoscopic criteria for sBCC were identified, as previously reported (4,79), with the presence of pink structureless areas, short superficial telangiectasias and arborizing microvessels in all 3 lesions.

RCM is currently the most promising non-invasive imaging technique for the quasi-microscopic characterization of skin tumors located between the stratum corneum and the superficial reticular dermis (10). RCM diagnostic features of BCC have been described (1012), including its superficial type (4,13). In particular, the presence of epidermal streaming, cords connected to the epidermis (4) or small (<300 µm), round tumor islands connected to the base of the epidermis and solar elastosis (13) were shown to differentiate sBCC from other BCC subtypes. In the cases reported herein, RCM imaging was performed prior to histopathological examination by means of a commercially available reflectance mode confocal laser scanning microscope (Vivascope 1500; Lucid Inc.). A detailed description of the technique and acquisition method has been reported elsewhere (14,15). The procedures were in accordance with the ethical standards of the institutional committee on human experimentation and with the 1975 Helsinki Declaration as revised in 1983.

Our results confirm the presence of previously identified RCM criteria for sBCC, demonstrating a good correlation with certain dermoscopic and histopathological findings (Table I). Moreover, some RCM morphologic features did not have a dermoscopic correspondent, emphasizing the complementarity of these two in vivo, non-invasive diagnostic techniques. Dark silhouettes, peritumoral clefts and solar elastosis are only some of these features. Dark silhouettes correspond to hypopigmented tumor islands and are visible as dark footprint-like shadows outlined by bright collagen (4). Clefts are defined as peritumoral, dark hyporefractile spaces (16) and dermal solar elastosis refers to the presence of highly refractile, coarse and thick collagen fibres in the dermis (17). Furthermore, some identified RCM characteristics could not be associated with specific histological patterns, suggesting that RCM may provide additional morphologic information, useful for the non-invasive characterization of BCC (4). One such example is the streaming of the epidermis, considered one of the most significant parameters for BCC diagnosis (11) and it refers to the elongated monomorphic keratinocyte nuclei that are oriented along the same axis, mostly observed in the spinous layer (11). In addition to that, plump cells defined as bright, oval or star-shaped cells, larger than inflammatory cells, are usually identified as melanophages or a specific type of inflammatory cells; however, there are limited immunohistochemical studies to differentiate between them (13).

Table I.

RCM morphological features and their dermoscopic and histopathological correlations identified in lesions from patients with sBCC.

Table I.

RCM morphological features and their dermoscopic and histopathological correlations identified in lesions from patients with sBCC.

RCM featureLesion no. 1Lesion no. 2Lesion no. 3Dermoscopic correlationHistopathological correlation
Altered honeycomb pattern+++Pleomorphic keratinocytes with atypical nuclei and scant cytoplasm
Nuclear streaming in the epidermis+++
Small and round to oval superficial refractile tumor islands+++Pink-white structureless areasFlattening of the rete ridge pattern and decrease/absence of melanin due to islands of basaloid tumor cells
Dark silhouettes++
Highly refractile dots, dendritic and granular structures+++Brown/blue-gray dotsMelanophages, melanocytes or melanin deposition within tumor islands at the dermoepidermal junction/papilllary dermis and/or located in the dermis
+++Blue-gray globules
Peripheral palisading of nuclei+Peripheral palisading at the periphery of tumor islands
Clefts+++Peritumoral cleft-like spaces corresponding to the peritumoral mucin deposition
Highly reflactile peritumoral fibrosis+++Thick collagen bundles surrounding tumor islands
Increased vasculature, with dilated and branched vessels+++Pink to red hue of the structureless areas. Short superficial telangiectasias. Arborising microvesselsAbundant blood capillaries, often with dilated and tortuous caliber, adjacent to basaloid islands
Inflammatory cells++Peritumoral inflammatory infiltrate consisting of lymphocytes, histiocytes
Plump cells+++Gray dots Melanophages/inflammatory cells
Bright dendritic shaped structures+Benign melanocytes, Langerhans cells
Erosions+ErosionsSmall loss of substance covered by hematic and lymphocytic exudates
Dermal solar elastosis+++Thickened, irregular basofilic collagen fibers in the dermis

[i] RCM, reflectance confocal microscopy; sBCC, superficial basal cell carcinoma.

In addition, this novel technology may be a diagnostic guide in defining the margins of the lesion prior to laser ablation (1) or surgical excision (18). Moreover, in contrast to invasive techniques, RCM also allows for the dynamic evaluation of skin vasculature in vivo, in real-time (19,20) and it offers the advantage of performing determinations to monitor tumor response to non-invasive treatment for sBCC (10).

In addition, RCM is a step forward in the evaluation of skin tumors at the cellular level and may contribute to unveiling the mechanisms of cancer development which are of overwhelming complexity (21,22).

In conclusion, in this study, we demonstrate that RCM, combined with dermoscopy allows for the rapid, in vivo, non-invasive micromorphological evaluation of sBCC, that may replace the histopathological examination in this subtype of BCC. However, further larger scale studies are warranted to further validate our findings if the implementation of RCM in daily dermatological practice is to become a reality.

Acknowledgements

This study was supported by the Sectorial Operational Programme Human Resources Development (SOPHRD), financed by the European Social Fund and the Romanian Government under the contract no. POSDRU 141531/2014, grant no. PN-II-PT-PCCA-2013-4-1407 (project 190/2014) financed by Executive Agency for Higher Education, Research, Development and Innovation and Young Researchers grant no. 33891/2014 financed by ‘Carol Davila’ University of Medicine and Pharmacy, Bucharest, Romania.

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Spandidos Publications style
Ghita MA, Caruntu C, Rosca AE, Kaleshi H, Caruntu A, Moraru L, Docea AO, Zurac S, Boda D, Neagu M, Neagu M, et al: Reflectance confocal microscopy and dermoscopy for in vivo, non-invasive skin imaging of superficial basal cell carcinoma. Oncol Lett 11: 3019-3024, 2016
APA
Ghita, M.A., Caruntu, C., Rosca, A.E., Kaleshi, H., Caruntu, A., Moraru, L. ... Tsatsakis, A.M. (2016). Reflectance confocal microscopy and dermoscopy for in vivo, non-invasive skin imaging of superficial basal cell carcinoma. Oncology Letters, 11, 3019-3024. https://doi.org/10.3892/ol.2016.4354
MLA
Ghita, M. A., Caruntu, C., Rosca, A. E., Kaleshi, H., Caruntu, A., Moraru, L., Docea, A. O., Zurac, S., Boda, D., Neagu, M., Spandidos, D. A., Tsatsakis, A. M."Reflectance confocal microscopy and dermoscopy for in vivo, non-invasive skin imaging of superficial basal cell carcinoma". Oncology Letters 11.5 (2016): 3019-3024.
Chicago
Ghita, M. A., Caruntu, C., Rosca, A. E., Kaleshi, H., Caruntu, A., Moraru, L., Docea, A. O., Zurac, S., Boda, D., Neagu, M., Spandidos, D. A., Tsatsakis, A. M."Reflectance confocal microscopy and dermoscopy for in vivo, non-invasive skin imaging of superficial basal cell carcinoma". Oncology Letters 11, no. 5 (2016): 3019-3024. https://doi.org/10.3892/ol.2016.4354