Archived Policies - Medicine



Effective Date:05-01-2008

End Date:07-31-2011


Dermatoscopy, using either direct inspection, digitization of images, ultraviolet photography or computer-assisted analysis is considered experimental, investigational and unproven as a technique to evaluate or serially monitor pigmented skin lesions.


Dermatoscopy describes a family of noninvasive techniques that allow in vivo microscopic examination of skin lesions, and is intended to help distinguish between benign and malignant pigmented skin lesions.  The technique involves application of immersion oil to the skin, which eliminates light reflection from the skin surface and renders the stratum corneum transparent. Using a magnifying lens, the structures of the epidermis and epidermal-dermal junction can then be visualized.  A handheld or stereomicroscope may be used for direct visual examination. Digitization of photographic images, typically after initial visual assessment, permits storage and facilitates their retrieval, and is often used for comparison purposes if a lesion is being followed up over time.

A variety of dermatoscopic features have been identified that are suggestive of malignancy, including pseudopods, radial streaming, the pattern of the pigment network, and black dots. These features in combination with other standard assessment criteria of pigmented lesions, such as asymmetry, borders, and color, have been organized into algorithms to enhance the differential diagnosis of pigmented skin lesions.  Dermatoscopic images may be assessed by direct visual examination or by review of standard, digitized or ultraviolet photographs.  Digitization of images, either surface or dermatoscopic images, may permit qualitative image enhancement for better visual perception and discrimination of certain features, or actual computer-assisted diagnosis.

Specialized clinics have been developed specifically to offer dermatoscopy.  The evaluation may be marketed as a “melanomagram.”  The MoleMax II ™ is a dermatoscopy device that includes a microscopic camera, image digitizer, storage and retrieval of images, and computer-aided diagnostic tools.

Dermatoscopy, which has been more widely investigated and adopted in Western Europe, may also, be referred to as dermoscopy, skin surface microscopy, incidence light microscopy, or epiluminescence microscopy.

Dermatoscopy has also been used to assess other conditions including vascular structures and chronic psoriasis (to monitor effects of long-term topical steroid therapy).

Ultraviolet photography is a photographic process of recording images by using light from the ultraviolet (UV) spectrum only.


As with any diagnostic tool, assessment, dermatoscopy involves a determination of its sensitivity, specificity, and positive and negative predictive values in different populations compared to a gold standard, and whether the results of the diagnostic tests are ultimately used to benefit health outcomes.  The gold standard for evaluation of pigmented skin lesions is excision with histologic diagnosis, for which, depending on the skill of the pathologist, sensitivity and specificity are considered near 100%.  The relevant health outcome is early diagnosis of a malignancy.  Clinically, dermatoscopy is used in combination with clinical assessment, based on either direct visual inspection or review of photographs.  Therefore, the diagnostic performance of dermatoscopy combined with clinical assessment must be compared with clinical assessment alone and then compared to the gold standard of histology.  There are three general clinical situations in which dermatoscopy might be of benefit.

  • Many patients present with an individual pigmented skin lesion, and a decision must be made whether or not its clinical appearance suggests malignancy and thus whether or not the skin lesion should be excised.  Given the importance of early identification of melanoma and the relative ease of excision, most suspicious skin lesions will be excised.  However, in many cases excised lesions turn out to be benign, and thus the patient has undergone excision unnecessarily.  Therefore, when patients present with a lesion with a low pretest possibility of malignancy, dermatoscopy could potentially be used to determine which lesions did not require excision, (i.e., a deselection process).  In this clinical situation, the negative predictive value of dermatoscopy is the most relevant diagnostic parameter.
  • Some patients may present with multiple suspicious pigmented skin lesions such that excision of all or even some of them is not possible.  In this clinical situation, a determination must be made which of the lesions is most clinically suspicious and requires excision.  In this setting, the positive predictive value of dermatoscopy is the most relevant diagnostic parameter.
  • Serial assessment of lesions over time, as a technique to prompt excision when a lesion changes shape or color, is commonly performed in patients with multiple pigmented lesions, or for lesions in locations difficult to excise.  Serial conventional photography has been used for the follow-up of pigmented lesions.  In addition, the use of digital photography has facilitated the storage and retrieval of images.  Serial assessment using digitized dermatoscopic images has also been suggested.  Both the positive and negative predictive values of the results of serial imaging using clinical or dermatoscopic assessment are relevant.  For example, do dermatoscopic changes precede clinical changes, thus increasing the sensitivity and positive predictive value of clinical assessment?

A variety of studies have reported on the diagnostic parameters of dermatoscopy criteria compared to clinical assessment with histologic examination serving as the gold standard. Unfortunately, most studies are retrospective and most compare clinical assessment only to dermatoscopic assessment of stored photographs instead of the more clinically relevant comparison of clinical assessment alone compared with combined clinical and dermatoscopic assessment.  In addition, the studies do not subcategorize lesions into varying levels of pretest probabilities, as outlined.  Few studies have specifically looked at the use of dermatoscopy as a serial monitoring tool.  There were no studies identified that specifically looked at the potential diagnostic advantages of digitization of images as opposed to conventional photography.  The majority of the studies report on the performance of clinicians who have extensive experience with dermatoscopic imaging, and thus whether or not these results can be duplicated in a community setting, or what kind of formal training would be required are other issues.  Finally, there is extensive discussion in the literature regarding the optimal dermatoscopic criteria for malignancy and the optimal method of using the criteria to assess malignancy.  For example, dermatoscopic images may be evaluated qualitatively, with semiquantitative scoring according to algorithms, evaluated using statistical methods to assess risk of malignancy, or evaluated using artificial neural networks.  Dermatoscopic criteria for malignant melanoma have undergone multiple modifications, with questions raised regarding their validity and reproducibility.  This variety of methods obviously complicates the evaluation of the data.  

Soyer and colleagues reported on a series of 159 pigmented skin lesions, including 65 melanomas.  The patients were members of a population referred to a dermatology clinic because of a pigmented skin lesion that was difficult to diagnose on clinical grounds alone.  Each lesion was clinically assessed by one of the investigators and the clinical diagnosis noted.  Each lesion was then examined dermatoscopically and a dermatoscopic diagnosis noted.  It is not clear whether the same clinician provided the clinical and dermatoscopic diagnosis.  The sensitivity and specificity of diagnosing malignant melanoma based on clinical assessment or dermatoscopy alone were the same:  94% and 82%.  However, if clinical assessment was combined with dermatoscopy, the sensitivity rose to 95%, with a specificity of 80%.

Binder and colleagues reported on a study of 240 pigmented skin lesions, photographed both with surface photography and with dermatoscopy.  (Both images were magnified 16 times). Histologic diagnosis was available for all.  The resulting 480 photographs were presented randomly and in an unpaired fashion to a group of six dermatoscopy experts and thirteen dermatologists who were not specifically trained in dermatoscopy.  Although not explicitly described, evaluation of the dermatoscopic images was presumably qualitative.  To assess intraobserver variability, 24 pairs of slides were presented twice.  The slides were arranged such that corresponding pairs of slides from an individual lesion were not presented sequentially, and thus the clinically relevant combined assessment of surface and dermatoscopic images for a single lesion was specifically excluded.  Among the 240 lesions, about 24% were malignant melanoma and 17.5% were histologically classified as a dysplastic nevus.  The rest were benign lesions.  Among the dermatoscopic experts, the intraobserver agreement was 0.57 for surface photography versus 0.56 for dermatoscopy.  The intraobserver agreement was 0.40 for surface microscopy versus 0.47 for dermatoscopy, indicating only a moderate degree of agreement for either technique.  The median sensitivity and specificity for surface microscopy in detecting malignant melanoma was 58% and 91%, respectively, compared to 68% and 91%, respectively, for dermatoscopy.  While the improvement in sensitivity from 58% to 68% was clinically significant (p=0.02), the more clinically relevant positive and negative predictive values were not reported.  In addition, the sensitivity of dermatoscopy among non-experts actually significantly decreased compared to surface photography.  A subsequent study by Binder reported that short-term formal training improves the diagnostic performance of dermatologists.

Cristofolini and colleagues reported on a series of 220 pigmented skin lesions in which the diagnostic parameters of clinical assessment, dermatoscopic assessment, and combined assessment were compared with histology.  The sensitivity and specificity of the techniques are summarized below:


Sensitivity (%)

Specificity (%)

Clinical Assessment Alone









Nachbar and colleagues reported on a semiquantitative method of evaluation of 172 dermatoscopic images compared to a clinical assessment.  The ABCD rule of dermatoscopy was applied (asymmetry, border, color, differential structure) and those scoring above or below 5.45 were classified as malignant or benign, respectively.  The following results were reported:


Sensitivity (%)

Specificity (%)

Positive Predictive Value

Negative Predictive Value











As noted above, while dermatoscopy was associated with an improved negative predictive value, it is unlikely that a negative predictive value of 85% would be adequate to eliminate consideration of excision.  In addition, it is not known whether the improvement of the positive predictive value from 90% to 96% is statistically or clinically significant.

Ascierto and colleagues reported on a series of 8,782 subjects with 15,719 skin lesions evaluated dermatoscopically.  Based on dermatoscopic assessment the lesions were further classified from very low to very high risk for malignant melanoma.  Excision was advised for all high-risk lesions.  In medium- and low-risk lesions, excision was justified for cosmetic or functional reasons.  The sensitivity and specificity of dermatoscopy were then compared to the histologic results of the 2,731 excised lesions.  For very high- and high-risk lesions, the positive and negative predictive value of dermatoscopy was 86.4% and 96.6%, respectively.  In the low-risk group, the positive and negative predictive values were 93.1% and 95.4%, respectively.  There are no data regarding the diagnostic performance of dermatoscopy compared to clinical assessment alone, or in combination with dermatoscopy.

Only one study was identified that specifically examined the role of dermatoscopy in the serial monitoring of lesions.  Kittler and colleagues reported on 1,862 sequentially digitally recorded dermatoscopic images from 202 patients with multiple clinically atypical nevi.  Excision was recommended if substantial modifications in the dermatoscopic images were noted.  A total of 75 lesions from 52 patients were excised; 67 (89.3%) were histologically diagnosed as benign lesions.  The eight malignant lesions showed a change in size in addition to appearance of dermatoscopic structures that are associated with malignancy.  It is unclear from these data whether or not dermatoscopic evaluation can better target changing lesions for excision.  In addition, the study did not compare the use of serial dermatoscopy with serial surface photography.

While there is extensive literature regarding dermatoscopy, the literature is inconclusive regarding its clinical role in the management of pigmented skin lesions, (i.e., as a technique to either select or deselect lesions for excision), which is considered the gold standard.  Only one study mimicked the actual clinical practice of combining clinical assessment with dermatoscopic assessment and compared its diagnostic performance to clinical assessment alone.  While this study reported an improved sensitivity with the combined technique, it is not clear whether the improved sensitivity is statistically or clinically significant.  There are inconclusive data regarding the role of serial dermatoscopic monitoring compared to serial clinical monitoring and inadequate data regarding computer-assisted analysis of dermatoscopic lesions.  Since there is inadequate documentation regarding the clinical value of dermatoscopy in various clinical situations, its use in conjunction with clinical assessment is considered not medically necessary.  There are inadequate data regarding the use of digitized photographs compared to conventional photographs.

Specifically, the recent medical literature was reviewed according to the problem formulation posed in the original medical policy rationale; that is, what is the positive predictive value of dermatoscopy (identifies lesions that require excision) and what is the negative predictive value of dermatoscopy (identifies lesions that do not require excision).  In addition, how does the predictive value of dermatoscopy compare to current clinical evaluation methods?  Studies that compare the results of traditional clinical evaluation to traditional clinical evaluation and dermatoscopy would be most informative.

A review of the recent literature did not reveal any recent original clinical studies that compared traditional clinical evaluation of pigmented lesions to dermatoscopy, or that compared dermatoscopy and traditional clinical evaluation to traditional clinical evaluation alone.  A meta-analysis of eight previous studies involving 328 melanomas and 1,865 mostly melanocytic benign pigmented lesions found that, for experienced users, dermatoscopy is more accurate than clinical examination for the diagnosis of melanoma in a pigmented lesion.  However, the authors conclude that the roles of the number of lesions analyzed, the percentage of melanoma lesions, the instruments used, and dermatoscopy criteria used in each study could not be proved.

One study attempted to identify specific findings with dermatoscopy that are most predictive of eventual pathology confirmation of melanoma.  The study concludes that, in the hands of experienced dermatoscopy users, the presence of three or more colors seen in the lesion by dermatoscopy was the most powerful identifying feature of lesions subsequently shown on pathologic examination to be melanoma.  The study did not compare the predictive ability of dermatoscopy to identify melanoma relative to the predictive ability of traditional visual examination to identify histologically confirmed melanoma in a three or more colored lesion.

One study was based on dermatoscopic images of more than 2,000 benign and 115 malignant pigmented lesions and histopathologic slides.  The study identified three cases in which melanoma could have been histologically missed as a result of improper sectioning.  The authors suggest that combined dermatoscopic-histopathologic correlation can improve the diagnosis of melanoma.

A search of the MEDLINE database for the period of June 2006 through November 2007 identified a number of studies from Europe that focused on test accuracy, reporting standards, and/or when/how dermatoscopy might be best used in practice.  One of these studies compared dermatoscopy using three algorithmic methods with clinical diagnosis in 198 consecutive atypical macular melanocytic lesions.  Compared against the gold standard of histopathologic diagnosis, dermatoscopy with pattern analysis and the ABCD method had similar sensitivity (85% vs. 84%).  Specificity (79% vs. 75%) and positive predictive value (80% and 76%) were modestly higher for pattern analysis.  Results with the seven-point checklist were sensitivity of 78% and specificity of 65%.  Another study retrospectively compared dermatoscopy with naked-eye diagnosis based on a single clinician’s experience in 204 consecutive patients (206 lesions 3 mm or less).  Although sensitivity was higher with dermatoscopy (83% vs. 43%), specificity was lower (69% vs. 91%).  A third study assessed whether more melanocytic lesions would be selected for excision or follow-up based on whole body dermatoscopy in comparison with the common practice of clinical pre-selection of lesions for dermatoscopic evaluation.  Although more suspicious lesions were identified by whole body dermatoscopy, results were not compared with histopathological analysis, the gold standard.  Thus, it can not be determined if the procedure resulted in early positive identification of more melanoma lesions, or if it resulted in more unnecessary excisions of non-malignant lesions.  Overall, there still is a lack of rigorous data that demonstrates the impact of this technology on clinical outcomes, and no studies were identified relating specifically to the use of ultraviolet photography used for dermatoscopy.


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The information contained in this section is for informational purposes only.  HCSC makes no representation as to the accuracy of this information.  It is not to be used for claims adjudication for HCSC Plans.

Centers for Medicare and Medicaid (CMS) does not have a national coverage position.  Medicare coverage may be subject to local carrier discretion.

A national coverage position for Medicare may have been developed or changed since this medical policy document was written.  See Medicare's National Coverage at <>.


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Nachbar, F., Stolz, W., et al.  The ABCD rule of dermatoscopy.  High prospective value in the diagnosis of doubtful melanocytic skin lesions.  Journal of the American Academy of Dermatology (1994) 30:551-9.

Cristofolini, M., Zumiani, G., et al.  Dermatoscopy: usefulness in the differential diagnosis of cutaneous pigmented lesions.  Melanoma Research (1994) 4:391-4.

Binder, M., Schwarz, M., et al.  Epiluminescence microscopy.  A useful tool for the diagnosis of pigmented skin lesions for formally trained dermatologists.  Archives of Dermatology (1995) 131:286-91.

Stanganelli, I., Burroni, M., et al.  Intraobserver agreement in interpretation of digital epiluminescence microscopy.  Journal of the American Academy of Dermatology (1995) 66:584-9.

Soyer, H.P., Smolle, J., et al.  Diagnostic reliability of dermoscopic criteria for detecting malignant melanoma.  Dermatology (1995)190:25-30.

Argenyi, Z.B.  Dermoscopy (epiluminescence microscopy) of pigmented skin lesions.  Current status and evolving trends.  Dermatology Clinics (1997) 15:79-95.

Binder, M., Puespoeck-Schwarz, M., et al.  Epiluminescence microscopy of small pigmented skin lesion.  Short-term formal training improves the diagnostic performance of dermatologists. Journal of the American Academy of Dermatology (1997) 36:197-202.

Argenziano, G., Fabbrocini, G., et al.  Epiluminescence microscopy for the diagnosis of doubtful melanocytic skin lesions.  Comparison of the ABCD rule of dermatoscopy and a new 7-point checklist based on pattern analysis.  Archives of Dermatology (1998)134:1563-70.

Andreassi, L., Perotti, R., et al.  Digital dermoscopy analysis for the differentiation of atypical nevi and early melanoma: a new quantitative seminology.  Archives of Dermatology (1999) 135:1459-65.

Ascierto, P.A., Palmieri, G., et al.  Sensitivity and specificity of epiluminescence microscopy: evaluation on a sample of 2731 excised cutaneous pigmented lesions.  British Journal of Dermatology (2000) 142:893-8.

Kittler, H., Pehamberger, H., et al.  Follow up of melanocytic skin lesions with digital epiluminescence microscopy: patterns of modifications observed in early melanoma, atypical nevi, and common nevi.  Journal of the American Academy of Dermatology (2000) 43:467-76.

Bafounta, M., Beauchet, A., et al.  Is dermoscopy (epiluminescence microscopy) useful in the diagnosis of melanoma?  Results of a meta-analysis using techniques adapted to the evaluation of diagnostic tests.  Archives of Dermatology (2001) 137(10):1343-50.

Bauer, J., Metzler, G., et al.  Dermatoscopy turns histopathologist’s attention to the suspicious areas in melanocytic lesions.  Archives of Dermatology (2001) 137(10):1338-40.

Dermatoscopy.  Chicago, Illinois: Blue Cross Blue Shield Association Medical Policy Reference Manual. (2001 August 15) Medicine 2.01.42.

Bono, A., Bartoli, C., et al.  Melanoma detection.  A prospective study comparing diagnosis with the naked eye, dermatoscopy and telespectrophometry.  Dermatology (2002) 205(4):362-6.

Mackie, R.M., Fleming C., et al.  The use of the dermatoscope to identify early melanoma using the three-colour test.  British Journal of Dermatology (2002) 146(3):481-4.

Stolz, W., Semmelmayer, U., et al.  Principles of dermatoscopy of pigmented skin lesions.  Seminars in Cutaneous Medicine and Surgery (2003 March) 22(1):9-20.

Kuo, H.W., Ohara, K.  Pigmented eccrine poroma:  a report of two cases and study with dermatoscopy.  Dermatologic Surgery (2003 October) 29(10):1076-9.

Anantha, M., Moss, R.H., et al.  Detection of pigment network in dermatoscopy images using texture analysis.  Computerized Medical Imaging and Graphics (2004 July) 28(5):225-34.

Fleischer, A.B.  Dermatoscopy and the 51naked eye51.  Journal of the American Academy of Dermatology (2005 January) 52(1):178-9.

Angenziano, G., Puig, S., et al.  Dermoscopy improves accuracy of primary care physicians to triage lesions suggestive of skin cancer.  Journal of Clinical Oncology (2006) 24(12):1877-82.

Bono. A., Tolomio, E., et al.  Micro-melanoma detection: a clinical study on 206 consecutive cases of pigmented skin lesions with a diameter < or = 3 mm.  British Journal of Dermatology (2006) 155(3):570-3.

Seidenari, S., Longo, C., et al.  Clinical selection of melanocytic lesions for dermoscopy decreases the identification of suspicious lesions in comparison with dermoscopy without clinical preselection.  British Journal of Dermatology (2006) 154(5):873-9.

Annessi, G., Bono, R., et al.  Sensitivity, specificity, and diagnostic accuracy of three dermoscopic algorithmic methods in the diagnosis of doubtful melanocytic lesions: the importance of light brown structureless areas in differentiating atypical melanocytic nevi from thin melanomas.  Journal of the American Academy of Dermatology (2007) 56(5):759-67.

Dermatoscopy.  Chicago, Illinois: Blue Cross Blue Shield Association Medical Policy Reference Manual. (2007 December) Medicine 2.01.42.

Policy History:

5/1/2008          Revised/Updated Entire Document

3/15/2006        Revised/Updated Entire Document

8/15/2003        New Medical Document

Archived Document(s):

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