Dermatology: Practical and Conceptual


DERMATOLOGY PRACTICAL & CONCEPTUAL
www.derm101.com

Background: The incidence of nodular melanoma (NM) has been consistently described as at least 
10-15% of total melanomas for over 15 years despite advances in diagnostic algorithms and medical 
technology. NMs are strongly correlated with faster rates of growth and poorer prognosis and thus 
provide clinicians with a challenge for early recognition.

Objective: To evaluate diagnostic clues of consecutive histopathologically proven NMs in one general 
practice with particular emphasis on dermatoscopic characteristics and compare this to the published 
literature.

Method: A retrospective observational study was performed of five consecutive histologically proven 
NM, from a total of 212 consecutive melanomas from a general practice in Brisbane, Queensland, 
Australia. Dermatoscopic images, both polarized and non-polarized, which appears to be a unique 
resource, and dermatopathologic slides were available for all lesions.

Results: All of the NMs in this series were pigmented although one was hypomelanotic. Two of them 
were symmetrical. The most highly sensitive clues to NM were gray or blue structures and polarizing-
specific white lines.

Limitations: Due to the small number of NMs in this report no statistical significance can be attrib-
uted to the observational findings.

Conclusion: This small series supports what is already known: that a significant proportion of NMs 
may be dermatoscopically symmetrical but that known clues to melanoma are frequently present. 
Nodular lesions, pigmented or non-pigmented, should be excised to exclude NM if there is any clue to 
malignancy, regardless of symmetry, unless a confident specific benign diagnosis can be made.

ABSTRACT

Observation  |  Dermatol Pract Concept 2014;4(2):15 69

Nodular melanoma: five consecutive cases in a 
general practice with polarized and non-polarized 

dermatoscopy and dermatopathology
Cliff Rosendahl1, Matthew Hishon1, Alan Cameron1, Sarah Barksdale2, David Weedon2, 

Harald Kittler3

1 School of Medicine, The University of Queensland, Australia

2 Sullivan Nicolaides Pathology, Brisbane, Australia

3 Department of Dermatology and Venereology, Medical University of Vienna, Austria

Keywords: dermatoscopy, dermoscopy, dermatopathology, nodular, melanoma, nodular melanoma, polarizing-specific white lines, chrysalis 
structures

Citation: Rosendahl C, Hishon M, Cameron A, Barksdale S, Weedon D, Kittler H. Nodular melanoma: five consecutive cases in a general 
practice with polarized and non-polarized dermatoscopy and dermatopathology. Dermatol Pract Concept. 2014;4(2):15. http://dx.doi.
org/10.5826/dpc.0402a15

Received: July 29, 2013; Accepted: December 9, 2013; Published: April 30, 2014

Copyright: ©2014 Rosendahl 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: Cliff Rosendahl, MBBS, PhD, PO Box 734, Capalaba, Queensland, 4157Australia. Tel. +61 7 3245 3011; Fax. +61 
7 3245 3022. Email: cliffrosendahl@bigpond.com

mailto:cliffrosendahl@bigpond.com


70 Observation  |  Dermatol Pract Concept 2014;4(2):15

Introduction

Nodular melanoma (NM), defined as a melanoma with any junctional 

component extending no more than three rete ridges beyond the invasive 

component, is the second largest melanoma subtype, comprising 10-15% 

of melanomas in Caucasians [1]. NMs have been shown to have a faster 

growth rate (GR) (median GR 0.49 mm/month) than lentigo maligna mela-

nomas (median GR 0.13 mm/month) and superficial spreading melanomas 

(SSM) (median GR 0.12 mm/month) [2]. The GR of malignant melanomas 

(MM) has also been shown to be an independent prognostic indicator for 

the prediction of relapse after one year of follow up [3]. Studies have been 

performed in an attempt to determine diagnostic features, both clinical and 

dermatoscopic, which facilitate earlier diagnosis of NM, when Breslow 

thickness is less and prognosis therefore more favorable [4]. A general 

practice, with a special interest in skin cancer medicine and dermatoscopic 

photo-documentation of all treated lesions, provides a unique perspective 

on the evaluation of this condition.

Methods

A retrospective analysis was performed with respect to all NMs diagnosed 

between January 1, 2008, and June 30, 2013, in a general practice in 

Brisbane, Queensland, Australia. All lesions treated were prospectively 

recorded on the Skin Cancer Audit Research Database (SCARD) for both 

tracking and research purposes [5]. During the time interval of this study, 

five NMs were diagnosed from a total of 212 melanomas, 163 (76.8%) 

in-situ and 49 (23.2%) invasive. The percentage of melanomas which were 

nodular was therefore 2.4% of total melanomas and 10.2% of invasive 

melanomas. From January 1, 2008, to June 30, 2013, the ‘Number Needed 

to Treat’ (NNT) with respect to all melanomas diagnosed in this practice, 

calculated from the prospectively declared intention to confirm or exclude 

melanoma, was 5.36 [6].

Photo-documentation was routinely performed on all lesions submitted 

for histopathology, including clinical, macro and dermatoscopic images. 

Dermatopathologic copy-slides were also collected, catalogued and where 

appropriate, photographed. Dermatoscopic images were taken of all cases 

with a DermLite Fluid non-polarizing dermatoscope (3Gen, LLC) coupled 

to a Canon 50D digital camera (Canon USA, Inc.) and after October 2010, 

also with either a DermLite II HR polarized or DermLite DL3 (polarized 

and non-polarized) dermatoscope (3Gen, LLC) coupled to an Olympus 

E-450 digital camera (Olympus Corporation). Both non-polarized and 

polarized dermatoscopic images were available for each of the five NM.

Cases

The five cases of histologically diagnosed NM are presented in Tables 1 

and 2 with relevant clinical, dermatoscopic and dermatopathologic infor-

mation. In estimation of melanoma growth rate (GR) we used the ratio 

MM thickness/duration of the MM visible growth as defined in a previ-

ously described assessment tool [3]. Clinical images are displayed in Figure 

1, close-up images in Figure 2 and dermatoscopic and dermatopathologic 

images of each lesion are displayed in Figures 3 to 7.

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Observation  |  Dermatol Pract Concept 2014;4(2):15 71

Discussion
The incidence of NMs in this study was 10.2% (n=5/49) of 

invasive melanomas comparing to 10-15% in published large 

studies [4].

 TABLE 2. Dermatoscopy features of the series of five consecutive 
nodular melanomas listed in Table 1.*

Case Asymmetry
Blue/Black 
Structures

Gray/Blue 
Structures

Lines white 
(non-

polarized)

Lines white 
polarizing 

specific

Polymorphous 
vessels

1 yes no no yes yes yes

2 no yes yes yes yes yes

3 yes no yes no yes yes

4 yes yes yes no yes no

5 no yes yes no no no

*Asymmetry is defined as asymmetry of structure or color and is based on pattern, not outline. Blue/black structures are 
defined as blue/black color covering at least 10% of the lesion. Gray or blue structures are rated if these colors are seen on 
any part of the lesion. White lines (non-polarized) are rated if seen with non-polarizing dermatoscopy. Polarizing-specific 
white lines are white lines, perpendicularly orientated to each other, seen only with polarized dermatoscopy and polymor-
phous vessels are defined as a pattern including more than one vessel type. [Copyright: ©2014 Rosendahl et al.]

Figure 1. Clinical images of five consecutive nodular melanomas 

from a general practice. Case 1: A small brown nodule on non-sun-

damaged skin adjacent to the right areola on a 42-year-old man. 

Case 2: A blue nodule on sun-damaged skin on the right upper calf 

of a 75-year-old man. Case 3: A brown nodule on sun-damaged skin 

on the right lateral leg of an 85-year-old man. Case 4: A small blue 

nodule on sun-damaged skin on the upper calf of a 58-year-old man. 

Case 5: A very small brown nodule on non-sun-damaged skin on the 

back of a 62-year-old woman. [Copyright: ©2014 Rosendahl et al.]

a dermatoscope footplate. There is macular brown pigment on three 

sides. Case 2: A well demarcated shiny blue nodule with a regular 

border, with surface scale. Case 3: A well demarcated brown nodule 

with surface scale, more lightly colored centrally, with an eccentric 

darker area at one part of the slightly irregular border. Case 4: A 

well demarcated black nodule with an irregular border. Case 5: A 

well demarcated irregularly pigmented brown and black nodule with 

a markedly irregular border. [Copyright: ©2014 Rosendahl et al.]

Figure 2. Close-up images of 

the nodular melanomas dis-

played in Figure 1. Case 1: A 

well demarcated brown nod-

ule with a regular border, sur-

mounted by a pool of fresh 

blood following contact with 



72 Observation  |  Dermatol Pract Concept 2014;4(2):15

the doctor without the patient having any prior awareness 

of it (Case 5). This compares to the non-nodular melanomas 

in the same practice where only 9.6% (n= 20/207) were dis-

covered by the patient (of the remainder 14 were discovered 

by another doctor, 5 by another person and the remainder 

by the treating practitioner). We believe that this highlights 

the importance of patient education and awareness in the 

recognition of abnormal changes in skin lesions but it also 

illustrates the value of a clinician proceeding to examine the 

total skin surface when presented with any lesion of concern.

The clinical ABCD method is the most widely known 

algorithmic method for the clinical diagnosis of melanoma 

and has been promoted both to healthcare professionals and 

patients [10]. One of the criteria for melanomas to be detected 

using this method is that they have a minimum diameter of 6 

mm. It has been agreed among many authors that a significant 

proportion of NMs do not fulfil the ABCD criteria including 

the criterion of a minimum lesion size of 6mm [8,11]. In one 

series of eleven thin NMs (Breslow thickness 2 mm or less), 

63.6% (n=7/11) had a diameter of less than 6 mm [4]. Simi-

larly, in our series 60% (n=3/5) had a diameter less than 6mm 

and furthermore, each of these also had a Breslow thickness 

less than 2 mm.

One study of 1789 patients with melanoma found that 

NM was most frequently found in older men and most com-

monly on the lower limbs or head and neck [7]. In addition, it 

was shown to be more strongly correlated with actinic kera-

tosis rather than high nevi counts [7]. This suggests that NMs 

have an association with sun-damaged skin. In our series 80% 

(n= 4/5) were male and 75% (n=3/4) of these males were over 

50. With respect to body site, 60% (n=3/5) were on the leg 

(on sun-damaged skin) and 40% (n=2/5) were on the torso 

(on non-sun-damaged skin).

In a study involving 92 SSMs and 33 NMs, a higher 

proportion of NM was discovered by the patient (60.6%) 

compared to SSM (48.9%) [8], and in a study of 22 patients 

with NM, 61% were first detected by the patient and another 

17% detected by another family member and the patient [9]. 

In our series 60% (n= 3/5) were reported by the patient and 

another was known of by the patient, but this information 

was not volunteered until after the lesion was discovered 

(Case 4). In one case where the lesion was only 3 mm in 

diameter and on the posterior torso, it was discovered by 

Figure 3. Case 1: (A) Non- polarized dermatoscopic image; (B) Polar-

ized dermatoscopic image; (C, D and E) Dermatopathology images. 

White lines seen in both dermatoscopy images (perpendicularly orien-

tated in the polarized image) arguably correlate with vertical bands of 

collagen seen in the dermatopathologic overview (C). A mitotic Figure 

is seen centrally in (E). [Copyright: ©2014 Rosendahl et al.]

Figure 4. Case 2: (A) Non- polarized dermatoscopic image; (B) Po-

larized dermatoscopic image; (C, D and E) Dermatopathology im-

ages. The polarizing-specific perpendicular white lines are concen-

trated peripherally (B) and arguably correlate with vertical bands of 

collagen seen peripherally in the dermatopathologic images (C and 

D). [Copyright: ©2014 Rosendahl et al.]



Observation  |  Dermatol Pract Concept 2014;4(2):15 73

10% of the lesion had 78.2% sensitivity for melanoma [14]. 

The clue of ‘blue-black color’ was present in 60% (n=3/5) of 

the NMs in our series.

The clues to malignancy of gray or blue structures and 

polarizing specific white lines (defined as perpendicularly 

orientated white lines visible only on polarized dermatos-

copy) displayed the highest sensitivity for NM in our small 

consecutive series; each of them (n=5/5) had either one or the 

other clue and 60% (n=3/5) had both.

Polarizing-specific white lines were first named ‘chrysa-

lis structures’ [15] and were attributed to the presence of 

increased collagen, which has birefringent properties causing 

rapid randomization of polarized light thus making the col-

lagen more conspicuous. In a study by Balagula et al. it was 

found that in non-biopsied lesions these structures were most 

commonly found in dermatofibromas and scars, but in 265 

biopsied lesions including 20 melanomas they were observed 

With respect to dermatoscopic examination there were some 

similarities between the melanomas in our series (see Table 

2) and those in larger published studies.

It has been shown that in NM many of the classic derma-

toscopic features of SSM are lacking, however, irregularity 

of color is usually present in those that do contain pigment 

[12]. All of the melanomas in our series contained melanin 

pigment, although in one (Case 3) 75% of the lesion was 

non-pigmented and this would categorize it as an amelanotic/

hypomelanotic melanoma (AHM) [13].

In our series symmetry was present in 40% (n=2/5; Cases 

2 and 5) and if the accompanying nevus was ignored Case 1 

was also symmetrical; all were pigmented. The asymmetrical 

melanomas in our series were asymmetrical in both structure 

and color. In a published series of 33 NMs, 80% were sym-

metrical and 60.7% were classified as amelanotic [8]. In 

another published study 64% (n=7/11) of thin NMs (Breslow 

2 mm of less) were symmetrical and 18% (n=2/11) were clas-

sified as amelanotic [4].

A study of a series of 283 nodular pigmented lesions 

found that the presence of blue/black color covering at least 

Figure 5. Case 3: (A) Non- polarized dermatoscopic image; (B) Po-

larized dermatoscopic image; (C, D and E) Dermatopathology im-

ages. Polarizing-specific white lines are seen centrally (B) and argu-

ably correlate with dermatopathologic vertical collagen bands, not 

apparent in the overview (C) but seen in the central part of the lesion 

in the higher power view (D). [Copyright: ©2014 Rosendahl et al.]

Figure 6. Case 4: (A) Non- polarized dermatoscopic image; (B) Po-

larized dermatoscopic image; (C, D and E) Dermatopathology im-

ages. Heavily pigmented melanocytes concentrated in the dermis 

correlate with the structureless blue, caused by the Tyndall effect, 

seen in (A) and pagetoid nests and single cells in the epidermis cor-

relate with black clods and dots respectively seen in both (A) and 

(B). Polarizing-specific blue-white lines seen in (B) arguably corre-

late with vertical bands of collagen seen in (D). [Copyright: ©2014 

Rosendahl et al.]



74 Observation  |  Dermatol Pract Concept 2014;4(2):15

image (Figure 3C). In Case 2, polarizing specific white lines 

are seen peripherally (centrally is structureless white) and 

vertical collagen bands are seen peripherally in the derma-

topathology image (Figure 4D). In Case 3 no white lines are 

seen in the non-polarizing image—just a white structureless 

area—but they are seen centrally in the polarized image. Cor-

respondingly, vertical collagen bands, while not conspicuous 

in the low power view, are seen centrally in the medium-high 

power view (Figure 5D). In Case 4 the polarizing-specific lines 

are actually blue/white and there are no white or blue lines 

in the non-polarized view, just a very prominent structureless 

blue area. There is an abundance of collagen evident in the 

dermatopathology images of this case and significant vertical 

orientation of this is seen in the medium-high power view 

(Figure 6D). Case 5 is the exception in our series and con-

tains no dermatoscopic white lines in either the polarized on 

non-polarized images. Of significance, no vertically oriented 

bands of collagen are seen in any of the dermatopathological 

images of this case.

We believe this supports the hypothesis that polarizing-

specific white lines represent increased collagen production 

as vertically orientated bands, probably reflecting increased 

fibroblast activity related to the vertical growth phase of 

melanoma [16].

Conclusion

NM is a subtype of melanoma distinct from SSM both 

dermatopathologically and in its biological behavior. The 

presentation of five consecutive NMs with both polarized and 

non-polarized dermatoscopy provides a unique perspective 

on this lesion and supports what is already known: that a 

significant proportion of nodular melanomas may be derma-

toscopically symmetrical but that known clues to melanoma 

are frequently present. Every one of these five NMs, whether 

symmetrical or not, had either gray/blue color or polarizing-

specific white lines or both. The hypothesis that perpendicular 

white lines correlate to vertical bands of collagen related to 

the growth dynamics of invasive melanoma is supported 

by the fact that the four NMs in our series which displayed 

dermatoscopic polarizing-specific white lines also displayed 

dermatopathologic vertical bands of collagen in the dermis, 

while the one that did not have this feature had no dermato-

pathologic vertical collagen bands.

We would suggest that more NMs would be diagnosed 

earlier if nodular lesions with any known clue to malignancy 

were considered for biopsy regardless of symmetry. In par-

ticular, the clue of polarizing-specific white lines should lead 

to excision unless a confident specific benign diagnosis, for 

example, of dermatofibroma, can be made on historic and 

clinical grounds.

in 47.6% of basal cell carcinomas and 84.6% of invasive 

melanomas [16]. They were found to be more frequently 

observed in invasive melanomas than in-situ melanomas and 

their prevalence correlated to increased thickness of melano-

mas. In our series of 212 melanomas (23.2% n=49 invasive), 

both polarized and non-polarized dermatoscopy images were 

available in 142 (19.7% n=28 invasive). While 80% (n=4/5) 

of the nodular melanomas had polarizing-specific white 

lines only 7.2% (n=10/137) of the non-nodular melanomas 

displayed this feature and all but one of those were in-situ.

In Case 1 of our series the polarizing-specific white lines 

appear to correlate with white lines also seen with non-

polarized dermatoscopy and we speculate that they correlate 

with vertical bands of collagen seen in the dermatopathology 

Figure 7. Case 5: (A) Non- polarized dermatoscopic image; (B) Po-

larized dermatoscopic image; (C and D) Dermatopathology images. 

There are no dermatoscopic polarizing-specific white lines (B), and 

consistent with the hypothesis that these structures correlate to verti-

cal collagen bands, none of these are seen in the dermatopathologic 

images although abundant collagen surrounds nests of melanocytes 

(C and D). On the extreme left side (C and shown at high power 

in D) an eccrine duct can be seen attenuated by a large melanocyte 

nest which appears to be bulging into it. This would correlate with 

a dermatoscopic peripheral brown clod, as there is no apparent col-

lagen within or superficial to this nest to induce the Tyndall effect. 

[Copyright: ©2014 Rosendahl et al.]



Observation  |  Dermatol Pract Concept 2014;4(2):15 75

9. Bergenmar M, Hansson J, Brandberg Y. Detection of nodular 

and superficial spreading melanoma with tumour thickness 

< or = 2.0 mm—an interview study. Eur J Cancer Prev. 2002 

Feb;11(1):49–55.

10. Friedman RJ, Rigel DS, Kopf AW. Early detection of malignant 

melanoma: the role of physician examination and self-examina-

tion of the skin. CA Cancer J Clin 1985;35(3):130-51.

11. Kelly JW, Chamberlain AJ, Staples MP, McAvoy B. Nodular 

melanoma. No longer as simple as ABC. Aust Fam Physician. 

2003 Sep;32(9):706–9.

12. Segura S, Pellacani G, Puig S, et al. In vivo microscopic features of 

nodular melanomas: dermoscopy, confocal microscopy, and his-

topathologic correlates. Arch Dermatol. 2008 Oct;144(10):1311–

20.

13. Moloney FJ, Menzies SW. Key points in the dermoscopic diagnosis 

of hypomelanotic melanoma and nodular melanoma. J Dermatol. 

2011 Jan;38(1):10–5.

14. Argenziano G, Longo C, Cameron A, et al. Blue-black rule: a 

simple dermoscopic clue to recognize pigmented nodular mela-

noma. Br J Dermatol. 2011;165(6):1251-5.

15. Marghoob AA, Cowel L, Kopf AW, Scope A. Observation of 

chrysalis structures with polarized dermoscopy. Arch Dermatol. 

2009 May 1;145(5):618.

16. Balagula Y, Braun RP, Rabinovitz HS, et al. The significance 

of crystalline/chrysalis structures in the diagnosis of melano-

cytic and nonmelanocytic lesions. J Am Acad Dermatol. 2012 

Aug;67(2):194.e1–8.

References

1. Porras BH, Cockerell CJ. Cutaneous malignant melanoma: clas-

sification and clinical diagnosis. Semin Cutan Med Surg. 1997 

Jun;16(2):88–96.

2. Liu W, Dowling JP, Murray WK, et al. Rate of growth in melano-

mas: characteristics and associations of rapidly growing melano-

mas. Arch Dermatol. 2006 Dec;142(12):1551–8.

3. Grob JJ, Richard MA, Gouvernet J, et al. The kinetics of the visible 

growth of a primary melanoma reflects the tumor aggressiveness 

and is an independent prognostic marker: a prospective study. Int 

J Cancer. 2002 Nov 1;102(1):34–8.

4. Kalkhoran S, Milne O, Zalaudek I, et al. Historical, clinical, and 

dermoscopic characteristics of thin nodular melanoma. Arch 

Dermatol. 2010 Mar;146(3):311–8.

5. Rosendahl C, Hansen C, Cameron A, et al. Measuring perfor-

mance in skin cancer practice: the SCARD initiative. Int J Der-

matol. 2011 Jan;50(1):44–51.

6. Rosendahl C, Williams G, Eley D, et al. The impact of subspecial-

ization and dermatoscopy use on accuracy of melanoma diagnosis 

among primary care doctors in Australia. J Am Acad Dermatol. 

2012 Nov;67(5):846–52.

7. Chamberlain AJ, Fritschi L, Giles GG, Dowling JP, Kelly JW. 

Nodular type and older age as the most significant associations 

of thick melanoma in Victoria, Australia. Arch Dermatol. 2002 

May;138(5):609–14.

8. Chamberlain AJ, Fritschi L, Kelly JW. Nodular melanoma: pa-

tients’ perceptions of presenting features and implications for 

earlier detection. J Am Acad Dermatol. 2003 May;48(5):694–701.