Dermatology: Practical and Conceptual 208 Research | Dermatol Pract Concept 2018;8(3):12 DERMATOLOGY PRACTICAL & CONCEPTUAL www.derm101.com Potential utility of dermoscopy in the examination of ocular pigmentations Nida Kaçar1, Cem Yildirim2, Nese Demirkan3, Yunus Bulgu4 1 Department of Dermatology, Faculty of Medicine, Pamukkale University, Denizli, Turkey 2 Department of Ophthalmology, Faculty of Medicine, Pamukkale University, Denizli, Turkey 3 Department of Pathology, Faculty of Medicine, Pamukkale University, Denizli, Turkey 4 Department of Ophthalmology, Suhut Public Hospital, Afyonkarahisar, Turkey Key words: dermoscopy, ocular pigmentation, impression cytology, melanoma, melanocytic lesion Citation: Kaçar N, Yildirim C, Demirkan N, Bulgu Y. Potential utility of dermoscopy in the examination of ocular pigmentations. Dermatol Pract Concept. 2018;8(3):208-213. DOI: https://doi.org/10.5826/dpc.0803a12 Received: February 2, 2018; Accepted: May 7, 2018; Published: July 31, 2018 Copyright: ©2018 Kaçar et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Funding: None. Competing interests: The authors have no conflicts of interest to disclose. All authors have contributed significantly to this publication. Corresponding author: Prof. Nida Kaçar, MD, Pamukkale Universitesi Tip Fakultesi, Dermatoloji AD, E-309, Kinikli, Denizli, Turkey. Email: n_gelincik@yahoo.com. Background: Dermoscopy is a fundamental method in the examination of melanocytic neoplasms. Limited data exist about the dermoscopic features of ocular pigmentations (OPs). Objectives: We aimed to investigate the usefulness of dermoscopy in the examination of OPs. Methods: Dermoscopic images of OPs of 20 consecutive patients were recorded. Impression cytology (IC) was performed to these lesions. Dermoscopic images were evaluated for specific dermoscopic structures and patterns without knowing the cytological examination results. Results: Fifteen percent (3/20) of the lesions presented with suspicious cytological findings. More of the suspicious lesions had 4 colors compared to benign lesions (66.7% vs 11.8%, p=0.088). This was also determined for blue-gray (66.7% vs 11.8%, p=0.088) and white (66.7% vs 17.7%, p=0.14) colors. At least 3 structures were observed in all suspicious lesions (100%), but were observed in only in 41.2% of benign lesions (p=0.105). Besides, two-thirds of suspicious lesions had more than 4 struc- tures, but none of the benign lesions reported this (p=0.016). Most of the benign lesions showed asymmetry in one axis (93.3%), whereas all suspicious lesions showed asymmetry in 2 axes (p=0.004). Conclusions: Dermoscopy seems to be a useful method in the evaluation of OPs. The existence of dermoscopic patterns, colors, and dermoscopic structure plurality and asymmetry raise suspicion in OPs, similarly to skin pigmentations. Dermatologists should be aware of the ocular area, and closer collaboration should be developed between dermatologists and ophthalmologists in the management of pigmented lesions. ABSTRACT Research | Dermatol Pract Concept 2018;8(3):12 209 handheld dermatoscope (3Gen, San Juan Capistrano, CA) coupled with a Sony Cyber-Shot DSC-W35 camera (Sony Corporation, Zug, Switzerland) after removing the glass face- plate. The polarizing technology of the dermatoscope used in the present study allowed us to take dermoscopic images from a distance of approximately 1 cm without contact with the lesions. Impression cytology (IC) was performed on these lesions after dermoscopic imaging. Sampling was performed as follows: the eye was anesthetized with 1-2 drops of 0.5% proparacaine HCL (Alcaine) and the eyelids were opened for a few seconds to dry the conjunctiva to improve the adher- ence of cells to the cellulose acetate filter paper with a pore size of 0.45 (m. The cellulose acetate filter paper was pressed gently onto the surface of the OP; after 3-5 seconds, it was removed. The procedure was repeated 2-3 times to increase the sensitivity of the technique. The cellulose acetate filter paper was immediately fixed in 95% ethanol for 15 min- utes and stained by the Papanicolaou method, which was performed on the same day of collection. At this stage, the filter paper was placed in position with the cell sample fac- ing upward during staining, avoiding contamination and loss of material. After the coloration, it was mounted with Entellan (Millipore Sigma, Darmstadt, Germany) and filter paper on the slide. IC samples were screened in terms of nuclear size, nuclear- to-cytoplasmic ratio, irregular nucleus, irregular nuclear chromatin pattern, and prominent nucleoli, and subsequently graded into 4 different stages: 0 (insufficient material for diagnosis), 1 (normal epithelial conjunctival cells with or without melanin pigment, reactive conjunctival cells as seen in inflammation), 2 (melanocytes with mild atypia), 3 (melano- cytes with moderate atypia), and 4 (melanocytes with severe atypia) [9]. The amount of cells collected (low, moderate, high, very high) was noted for all samples [10]. The lesions with grade 1 or 2 atypia on IC samples were regarded as benign and those with grade 3 or 4 atypia as suspicious. Grade 0 IC samples were not taken under consid- eration [11]. Dermoscopic images were evaluated for specific dermoscopic structures and patterns by one of the authors (NK) without prior knowledge of the cytological examina- tion results. Fisher’s exact test was used for statistical analyses with SPSS software (version 18.0; SPSS Inc, Chicago, IL, USA). P values < 0.05 were considered significant. Power analysis was performed according to these results (for more than 4 structures, suspicious 66.7% and benign 0%) and it was determined that the present study had more than 80% power with 95% confidence. For the present study approval was obtained from the Medical Research Ethics Committee of the Faculty of Medi- Introduction The ocular surface includes the conjunctiva and the cor- nea. Specifically, melanocytic lesions that arise in this area are melanocytic nevus, racial melanosis, primary acquired melanosis, and melanoma. Melanocytic nevi are the most common melanocytic tumors of the conjunctiva. They gen- erally become clinically evident during the first and second decade of life. Typically, the conjunctival melanocytic nevi are pigmented, well defined, and elevated lesions. Approxi- mately 1% of melanocytic nevi evolve to melanoma. Racial melanosis presents commonly on the limbus as bilateral congenital, circular pigmentation. Ocular melanocytosis is also a congenital pigmentation status entertaining a mela- noma risk; it emerges unilaterally and involves periocular skin, the sclera, and orbita, but typically spares conjunctiva. Ocular melanocytosis is commonly confused with primary acquired melanosis, which is an acquired condition emerg- ing in middle age that presents with diffuse, patchy, poorly defined, and flat pigmentation. Thirteen percent of primary acquired melanosis lesions with atypia can also give rise to melanoma [1-3]. The reasons for conjunctival nevi excisions include fast growth, suspicious changes under biomicroscopic examination such as intrinsic vascularity and/or pigmenta- tion increase, cosmetic reasons, and patient concerns about malignancy [1,2,4]. Ocular melanoma arises from melano- cytes within the eye, including the uveal tract, conjunctiva, and orbit; it constitutes less than 5% of all melanoma cases. Conjunctival melanomas comprise only ~5% of ocular melanomas; however, the incidence has been increasing, as reported for cutaneous melanoma, which is being related to ultraviolet light exposure [5,6]. The rarity of conjunctival melanomas contributes to difficulties in their management. Slit-lamp biomicroscopy, high-resolution anterior seg- ment ultrasound, in vivo confocal microscopy, and optical coherence tomography constitute the noninvasive diagnostic technologies for evaluating ocular surface lesions [7]. Der- moscopy is one of the most important noninvasive technolo- gies being used in the diagnosis and follow-up of pigmented skin lesions [8]. In the present study, we aimed to investigate the usefulness of dermoscopy in the examination of ocular pigmentations (OPs). Materials and Methods Patients with ocular pigmentation older than 18 years old who presented to the Departments of Dermatology and Ophthalmology of the Faculty of Medicine of Pamukkale University between December 2010 and March 2012 were invited to participate in the study, prospectively. The lesions were examined clinically and dermoscopically. Dermoscopic images were taken with a DermLite Pro HR (polarizing) 210 Research | Dermatol Pract Concept 2018;8(3):12 (65%). Only 1 pattern was found in 6 (all benign), 2 patterns in 13 (11 benign, 2 suspicious) and 3 patterns in 1 lesion (suspicious). We found 4 lesions with only a sin- gle color (all benign), 11 (10 benign, 1 suspicious) with 2 colors, 1 (benign) with 3 colors, and 4 (2 benign, 2 sus- picious) with 4 colors. The most fre- quent color was light brown, which was present in 18 lesions (15 benign, 3 suspicious), followed by dark brown (16 lesions [13 benign, 3 suspicious]), white (5 lesions [3 benign, 2 suspi- cious]), blue-gray (4 lesions [2 benign, 2 suspicious]), and black (2 benign cine, Pamukkale University, and all par- ticipants gave their informed consent. Results T h e s t u d y e n r o l l e d 2 4 O P s f r o m to 23 patients. Four lesions of 3 patients were excluded because IC samples were grade 0 (insufficient material for diagnosis). Twenty OPs of 20 patients (12 males, 8 females) were included in total. The clinical diagnoses, based on clinical features including the localiza- tion, onset time, and morphological characteristics of the lesion and bio- microscopic findings were primary acquired melanosis in 6 lesions, Ota nevus in 1, melanocytic nevus in 12, and melanoma in 1 lesion. Three lesions showed grade 3 atypia (Figure 1). Two of the 3 cytologically suspicious lesions were clinically diagnosed as melano- cytic nevus; only 1 was suspicious from the clinical point of view. Biopsy was planned for these lesions; however, the patients did not agree. Two cytologically benign lesions could be followed up, and no change was observed in them when comparing their cytological diagnosis (Figure 2). Another cytologically benign lesion was removed at the request of the patient and the histopathological diag- nosis was compound nevus. Homogeneous and globular pat- terns were the dominant dermoscopic patterns in both benign lesions (seen in 14 and 13 lesions, respectively) and suspicious (3) lesions (Figure 3). These patterns coexisted in most of the lesions lesions). More of the suspicious lesions showed 4 colors compared to benign lesions (66.7% vs 11.8%, p=0.088). This was also determined for blue-gray (66.7% vs 11.8%, p=0.088) and white (66.7% vs 17.7%, p=0.14) colors. The most prevalent dermoscopic structure was the structureless area observed in 17 lesions (14 benign, 3 suspicious), followed by dots (13 benign, 3 suspi- cious), globules (11 benign, 3 suspi- cious), pigment network (1 benign, 2 suspicious) and streaks (1 benign, 2 suspicious). Only one dermoscopic structure was found in 1 lesion (benign), 2 struc- Figure 1. Cytological examination of the suspicious lesions of the 3 cases showing grade 4 atypia in the sheets of atypical melanocytes. (A) PAP ×10 and grade 3 atypia. (B) and (C) PAP ×20. [Copyright: ©2018 Kaçar et al.] Figure 2. No dermoscopic changes were observed within 6 months in the 2 observed lesions. [Copyright: ©2018 Kaçar et al.] Research | Dermatol Pract Concept 2018;8(3):12 211 prognosis [11]. Dermoscopy is a fundamental method in the examination of melanocytic neoplasms. It has been established that dermoscopic examination increases the diagnostic accuracy from 5% to 30% [10]. The whole skin, nails, and mucosa should be examined during melanoma screening. Although nails and oral and genital mucosa lesions have been routinely examined in addition to skin, dermatologists generally do not show interest in ocular mucosa. Therefore, there are not much data about the der- moscopic features of pigmentations on ocular mucosa in the literature. We observed light-brown-colored homogeneous pattern, a benign dermoscopic pattern [12], in the conjunc- tival pigmentation of a case of Laugier-Hunziker syndrome. IC of the pigmentation revealed melanocytes with only a mild atypia, suggesting a benign nature in accordance with the dermoscopic pattern we observed [13]. Atypical pig- ment network, irregular dots/globules, regression structures, and blue-white veil, all of which are melanoma-specific dermoscopic features, were reported in a case of palpebral conjunctival melanoma. Concordance was present between dermoscopic findings and diagnosis in that case as well [14]. tures in 9 lesions (all benign), 3 structures in 8 lesions (7 benign, 1 suspicious), 4 structures in 1 lesion (suspicious), and 5 structures in 1 lesion (suspicious). Three or more structures were observed in all suspicious lesions (100%), but in only 41.2% of the benign lesions (p=0.105). Two- thirds of suspicious lesions had more than 4 structures, but none of the benign lesions had this (p=0.016). Asymmetry was observed in all lesions except for 2 benign ones (90%). Most of the benign lesions showed asymmetry in one axis (93.3%), whereas all suspicious lesions showed asymmetry in 2 axes (p=0.004). Categorical comparisons are summa- rized in Table 1. Discussion The fields of dermatology and ophthalmology overlap in many ways, as a number of diseases involve both the eye and the skin. One of those diseases is melanoma. Derma- tologists have an important place in the management of skin melanoma. It has been established that the early detection of melanoma is the most effective intervention to improve Figure 3. (A), (B), and (C) Dermoscopic views of some OPs (original magnification ×10): (A) homogeneous, (B) reticular, and (C) homoge- neous-reticular dermoscopic patterns. (D), (E), and (F) Clinical views of some OPs. [Copyright: ©2018 Kaçar et al.] 212 Research | Dermatol Pract Concept 2018;8(3):12 changes in comparison to their cytological diagnosis; in addition, histopathological diagnosis of another cytologically benign lesion that was removed at the request of the patient was also benign. Conclusions According to our knowledge, the present study is the first prospective study to investigate the dermoscopic features of OPs. Our results demonstrated that dermoscopy is a useful method in the examination of OPs. Dermatologists should be aware of the ocular area in terms of possible melanoma involvement, and closer collaboration should be developed between dermatologists and ophthalmologists in the manage- ment of pigmented lesions. Acknowledgement The study was presented as a poster presentation at the 4th World Congress of Dermoscopy 2015 in Vienna, Austria. References 1. Kheir WJ, Tetzlaff MT, Pfeiffer ML, et al. Epithelial, non- melanocytic and melanocytic proliferations of the ocular sur- face. Semin Diagn Pathol. 2016;33(3):122-132. doi: 10.1053/j. semdp.2015.10.006. 2. Zalaudek I, Argenziano G, Di Stefani A, et al. Dermoscopy in general dermatology. Dermatology. 2006;212(1):7-18. doi: 10.1159/000089015. 3. Rayward O, Moreno-Martín P, Vallejo-Garcia JL, Vano-Galvan S. Ophthaproblem. Can you identify this condition? Conjunctival nevus. Can Fam Physician. 2011;57(10):1157, 1159-1160. 4. Shields CL, Shields JA. Tumors of the conjunctiva and cornea. Surv Ophthalmol. 2004;49(1):3-24. doi: 10.1016/j.survoph- thal.2003.10.008. 5. Blum ES, Yang J, Komatsubara KM, Carvajal RD. Clinical man- agement of uveal and conjunctival melanoma. Oncology (Wil- liston Park). 2016;30(1):29-32, 34-43, 48. 6. Shields CL, Kels JG, Shields JA. Melanoma of the eye: revealing hidden secrets, one at a time. Clin Dermatol. 2015;33(2):183-196. doi: 10.1016/j.clindermatol.2014.10.010. 7. Barros JN, Almeida SR, Lowen MS, Cunha MC, Gomes JÁ. Impression cytology in the evaluation of ocular surface tumors: review article. Arq Bras Oftalmol. 2015;78(2):126-132. doi: 10.5935/0004-2749.20150033. 8. Marino ML, Carrera C, Marchetti MA, Marghoob AA. Practice gaps in dermatology: melanocytic lesions and melanoma. Derma- tol Clin. 2016;34(3):353-362. doi: 10.1016/j.det.2016.03.003. 9. Levecq L, De Potter P, Jamart J. Conjunctival nevi clinical features and therapeutic outcomes. Ophthalmology. 2010;117(1):35-40. doi: 10.1016/j.ophtha.2009.06.018. 10. Braun RP, Rabinovitz HS, Oliviero M, Kopf AW, Saurat JH. Dermoscopy of pigmented skin lesions. J Am Acad Dermatol. 2005;52(1):109-121. doi: 10.1016/j.jaad.2001.11.001. 11. Breitbart EW, Waldmann A, Nolte S, et al. Systematic skin cancer screening in Northern Germany. J Am Acad Dermatol. 2012;66(2):201-211. doi: 10.1016/j.jaad.2010.11.016. Homogeneous, globular, starburst, and reticular patterns are the dermoscopic patterns seen most frequently in benign pigmented skin tumors. The presence of more than 2 der- moscopic patterns together suggests malignant nature. In addition, the presence of color and/or dermoscopic structure multiplicity and/or asymmetry also raises suspicion [12]. In the present study, we found that 4 colors, 3 or more dermo- scopic structures, asymmetry in 2 axes, and blue-gray or white colors are the dermoscopic findings that indicate a suspicious lesion. According to our results, dermoscopic pattern, color, and dermoscopic structure plurality and asymmetry should arouse suspicion in OPs, similarly to skin pigmentations. Particular attention should be paid to lesions with more than 4 structures and/or asymmetry in 2 axes. There are 2 limitations of our study. First, the sample size of our study is relatively small. Second, we only per- formed IC for the lesions. IC is an extensively used method to evaluate superficial epithelial layers of the ocular surface [7]. It was demonstrated that IC with cellulose acetate filters is able to sample deeper layers when performed repeatedly [15]. The major advantage of IC is to preserve the eye from unnecessary surgical procedures [7]. An increased nuclear-to- cytoplasmic ratio, an irregular nuclear chromatin pattern, the presence of large nucleoli, and the observation of mitosis and anisokaryosis have been suggested as malignant cytological features in melanin-containing cells [16]. Although the gold standard for diagnosis is histopathological examination, a 73% correlation was found between IC and histopathol- ogy in pigmented lesions from the conjunctiva, and biopore membrane IC was shown to accurately predict the outcome in 88% of the 127 histopathologically proven melanocytic lesions [16,17]. The positive and negative predictive accuracy of IC have been found to be 97.4% and 52.9%, respectively, when compared to histopathological findings in the diagno- sis of ocular surface neoplasia [18]. In conclusion, IC was proposed to be a useful noninvasive method in evaluating conjunctival nevi [19]. In our study, the 2 observed lesions with benign cytological features showed no dermoscopic TABLE 1. Categorical Comparisons Dermoscopic Features Benign Suspicious P value ≥4 colors 11.8 66.7 =0.088 Blue-gray color 11.8 66.7 =0.088 White color 17.7 66.7 =0.14 ≥3 structures 41.2 100 =0.105 ≥4 structures 0 66.7 =0.016 Asymmetry in 2 axes 5.9 100 =0.004 Research | Dermatol Pract Concept 2018;8(3):12 213 12. Jaimes N, Marghoob AA. The morphologic universe of mela- noma. Dermatol Clin. 2013;31(4):599-613, viii-ix. doi: 10.1016/j. det.2013.06.010. 13. Kaçar N, Yildiz CC, Demirkan N. Dermoscopic features of con- junctival, mucosal, and nail pigmentations in a case of Laugier- Hunziker syndrome. Dermatol Pract Concept. 2016;6(1):23-24. doi: 10.5826/dpc.0601a07. 14. Li K, Xin L. Palpebral conjunctiva melanoma with dermoscopic and clinicopathological characteristics. J Am Acad Dermatol. 2014;71(2):e35-e37. doi: 10.1016/j.jaad.2013.11.011. 15. Singh R, Joseph A, Umapathy T, Tint NL, Dua HS. Impression cy- tology of the ocular surface. Br J Ophthalmol. 2005;89(12):1655- 1659. doi: 10.1136/bjo.2005.073916. 16. Paridaens AD, McCartney AC, Curling OM, Lyons CJ, Hun- gerford JL. Impression cytology of conjunctival melanosis and melanoma. Br J Ophthalmol. 1992;76(4):198-201. doi: 10.1136/ bjo.76.4.198. 17. Keijser S, Missotten GS, De Wolff-Rouendaal D, et al. Impres- sion cytology of melanocytic conjunctival tumours using the Biopore membrane. Eur J Ophthalmol. 2007;17(4):501-506. doi: 10.1177/112067210701700404. 18. Tananuvat N, Lertprasertsuk N, Mahanupap P, Noppana- keepong P. Role of impression cytology in diagnosis of ocular surface neoplasia. Cornea. 2008;27(3):269-274. doi: 10.1097/ ICO.0b013e31815b9402. 19. Barros JN, Lowen MS, Mascaro VL, Andrade TP, Martins MC. Impression cytology features of conjunctival nevi reported as more noticeable. Arq Bras Oftalmol. 2009;72(2):205-210. doi: 10.1590/S0004-27492009000200014.