Dermatology: Practical and Conceptual


Review  |  Dermatol Pract Concept 2018;8(2):8 109

DERMATOLOGY PRACTICAL & CONCEPTUAL
www.derm101.com

Introduction

Ex vivo confocal microscopy (EVCM) is a an emerging imag-

ing technique that allows real-time microscopic examination 

of freshly excised cutaneous tissue that eliminates the need 

for standard embedding, processing, and sectioning that is 

necessary for conventional histology [1]. It enables a rapid 

examination of an entire skin sample directly in the surgical 

room. It has been mainly applied to the perioperative analysis 

of the surgical margins of basal cell carcinoma (BCC) during 

micrographic Mohs surgery (MMS). Notably, EVCM does 

not alter the tissue and does not prevent subsequent histo-

pathological examination.

Many possible applications are under investigation, such 

as the study of skin tumors other than BCC, the evaluation of 

skin appendages, and the diagnosis of skin infections. We aim 

to give an overview of the current available applications for 

this new device. The review was performed using the PubMed 

database. Search terms employed were ‘‘ex vivo,’’ ‘‘reflectance 

confocal microscopy,’’ “confocal laser scanning microscopy,” 

‘‘fluorescence confocal microscopy,’’ “skin,” “dermatology,” 

and “surgery.”

Ex vivo confocal microscopy: an emerging 
technique in dermatology

Elisa Cinotti1, Jean Luc Perrot2, Bruno Labeille2, Frédéric Cambazard2, Pietro Rubegni1

1 Department of Medical, Surgical and Neurological Science, Dermatology Section, University of Siena, S. Maria alle Scotte Hospital, Siena, 

Italy

2 Department of Dermatology, University Hospital of Saint-Étienne, Saint-Étienne, France

Key words: confocal microscopy, dermatology, ex vivo, fluorescence, skin, reflectance

Citation: Cinotti E, Perrot JL, Labeille B, Cambazard F, Rubegni P. Ex vivo confocal microscopy: an emerging technique in dermatology. 
Dermatol Pract Concept. 2018;8(2):109-119. DOI: https://doi.org/10.5826/dpc.0802a08

Received: July 3, 2017; Accepted: January 18, 2018; Published: April 30, 2018

Copyright: ©2018 Cinotti 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: Elisa Cinotti, PhD. Department of Medical, Surgical and Neurological Science, Dermatology Section, University 
of Siena, S. Maria alle Scotte Hospital, Viale Bracci 16, 53100 Siena, Italy. Tel: 0039-0577 585428. Fax: 0039 0577585484. Email: 
elisacinotti@gmail.com

This review aims to give an overview of the current available applications of ex vivo confocal micros-
copy (EVCM) in dermatology. EVCM is a relatively new imaging technique that allows microscopic 
examination of freshly excised unfixed tissue. It enables a rapid examination of the skin sample direct-
ly in the surgery room and thus represents an alternative to the intraoperative micrographic control 
of the surgical margins of cutaneous tumors by standard microscopic examination on cryopreserved 
sections during Mohs surgery. Although this technique has mainly been developed for the margin’s 
control of basal cell carcinoma, many other skin tumors have been studied, including melanoma. Use 
of EVCM is continuing to evolve, and many possible applications are under investigation, such as the 
study of nails and hair diseases and the diagnosis of skin infections.

ABSTRACT



110 Review  |  Dermatol Pract Concept 2018;8(2):8

In reflectance mode, the images appear in grayscale with 

dark hypo reflective structures (black and dark gray) and 

bright hyper reflective structures (white and light gray) 

with an identical appearance to in vivo reflectance confocal 

microscopy (Figure 1). In the fluorescence mode, the non-

fluorescent structures are dark (black and dark gray) and the 

fluorescent structures are white (Figure 2). Using acridine 

orange, the nuclei of the cells are fluorescently stained in 

white with an increase in contrast of keratinocytes, hair fol-

licle epithelium, sebaceous and eccrine glands, fibroblasts 

(Figure 2), and tumor cells (Figure 3) relative to the sur-

rounding tissue.

Different from in vivo reflectance confocal microscopy, 

muscle and adipose tissue can be seen, given the opportunity 

to observe the sample from its lateral sides (Figures 1, 2) and 

its bottom. It should be noted that fat tissue is usually modi-

fied by fixation during classical histology, whereas fat remains 

intact under EVCM.

Interestingly, the same specimen can be observed both 

under the reflectance and fluorescence mode and the combi-

nation of the two techniques can give complementary infor-

mation on the architectural and cellular features.

Applications

EVCM has been shown to be a reliable diagnostic method 

with good histological correspondence for both normal 

and pathological skin [5,6,10]. It has been developed as an 

alternative to the optical microscopy examination of frozen 

sections stained with hematoxylin and eosin (H&E) for 

the intraoperative control of surgical margins of cutaneous 

tumors during MMS [4,7,10-13].

EVCM has also been used for intraoperative examination 

of nails [14,15] and can be employed for the evaluation of 

hair morphology [16] (Figure 4) and disease of the mucosa 

[17,18]. Mosaicing may offer a means to perform rapid his-

tology at the bedside. Several future applications are possible, 

such as the identification of fillers in the skin [19] and the 

diagnosis of inflammatory and infectious diseases [20-22].

EVCM cannot replace conventional histological examina-

tion because the cytological and architectural details cannot 

always be clearly identified, and to date, there is no specific 

staining that allows us to distinguish between different cell 

types. However, EVCM could be useful in some conditions 

in which the cellular and architectural abnormalities are 

more characteristic (Figure 5). Recently, EVCM has extended 

to other disciplines that might require extemporaneous 

examination of tumors, such as brain, breast and thyroid 

tumors [6,23-25]. A possible barrier to more widespread 

use of EVCM is that the mosaics are based on a single mode 

of grayscale contrast and appear black and white, whereas 

histology is based on two stains (hematoxylin for nuclei and 

Ex vivo Confocal Microscopy 
Examination

Microscope

Only one device is commercially available (VivaScope 2500(r), 

new version of VivaScope 2000, produced by Caliber, New 

York, USA and distributed in Europe by MAVIG GmbH, 

Munich, Germany). The ex vivo confocal microscope works 

in reflectance mode (laser wavelength of 830 nm) or fluores-

cence mode (laser wavelength of 488 nm or 658 nm).

Processing

In reflectance mode no staining is required. However, alumi-

num chloride, acetic acid, or citric acid can be used to enhance 

the reflectance of nuclei [2-4]. When using the fluorescence 

mode, the entire surgical specimen is dipped in a solution of a 

fluorescent agent (e.g., acridine orange, methylene blue, fluo-

rescein, Nile blue, or Patent Blue V) for 10-20 seconds and 

rinsed in physiological saline, acetic acid or phosphate buff-

ered saline in order to remove the excess of the fluorescent 

agent. The most used fluorescent agent is acridine orange that 

targets nuclear DNA [2]. Several studies showed that acridine 

orange immersion does not affect subsequent frozen sections 

and formalin-fixed histopathology quality [5-7].

Cutting in thin slices is not necessary. The skin specimen 

can be observed entirely, or the tumor’s margins can be verti-

cally cut as for conventional histology [8].

In order to prevent sample deformation and movement 

during the examination, the skin sample should be mounted 

between two thick microscopy glass slides attached together 

by a small amount of silicon glue or modeling clay [9]. To 

facilitate the contact of the outer surface of the specimen 

with the glass slide facing the microscope objective, aque-

ous gel (e.g., Carbomer gel, Gel Larmes Thea Laboratories, 

Clermont-Ferrand, France) or silicone can be applied [9]. A 

“tissue press” can be used to better flatten the sample [9] and 

avoid to artifacts that result from the inhomogeneous contact 

between the sample’s surface and the glass slide in the case of 

a specimen with a inhomogeneous thickness. The skin sample 

is then settled on the microscope stage.

Ex vivo Confocal Microscopy Images

The microscope produces horizontal images of 750 x 750 

µm of the different layers of the skin up to a thickness of 200 

µm. Single images are automatically stitched together into a 

reconstructed mosaic image to a maximum size of 20 x 20 mm 

(12 x12 mm for the previous generation of the device, the one 

that is most utilized). The depth of observation is manually 

adjusted. The acquisition time for a single image of 750 x 750 

µm is 0.68 seconds (2 minutes/cm2) for the third generation of 

the device [8]. According to the manufacturer’s data, the lateral 

and axial spatial resolutions are 1 µm and 3 µm respectively.



Review  |  Dermatol Pract Concept 2018;8(2):8 111

Figure 1. Normal skin under the ex vivo confocal microscope in the reflectance mode. Epidermis (red bracket), dermis (yellow bracket), 

and fat tissue (yellow asterisks) are visible in a vertical section. [Copyright: ©2018 Cinotti et al.]

Figure 2. Normal skin under ex vivo confocal microscope in fluorescence mode with acridine orange. Epidermis (red bracket), dermis 

(yellow bracket), fat tissue (yellow asterisk), and adnexa (pink asterisks) are visible in a vertical section. [Copyright: ©2018 Cinotti et al.]



112 Review  |  Dermatol Pract Concept 2018;8(2):8

Figure 3. Superficial basal cell carcinoma under ex vivo confocal microscope in fluorescence mode with acridine orange in a vertical sec-

tion. Tumor islands (blue circles) are easily recognizable because they are brighter (fluorescent) than the surrounding tissue. [Copyright: 

©2018 Cinotti et al.]

Figure  4. Normal hair shafts 

under ex vivo reflectance con-

focal microscopy. [Copyright: 

©2018 Cinotti et al.]



Review  |  Dermatol Pract Concept 2018;8(2):8 113

proposed for other epithelial tumors [32,33], melanocytic 

tumors [6,17,34,35] (Figure 7), and Paget’s disease [36] 

(Figure 8).

The overall sensitivity and specificity of fluorescence-

mode EVCM for detecting BCC with narrow or incom-

plete margins were 88–96.6% and 89.2–99% respectively 

[4,7,10,27,30]. The largest study performed by Bennàssar 

and colleagues on 80 carcinomas demonstrated an overall 

sensitivity and specificity for residual BCC of 88% and 99% 

respectively [10].

Possible false positive results can be caused by the pres-

ence of hair follicles and eccrine glands or sebaceous glands 

that may be confused with BCC islands. However, the former 

reveals no palisading, less fluorescence, and smaller nuclei. 

Furthermore, it could be difficult to distinguish the infiltra-

tive cords of BCC from the surrounding peritumoral stroma, 

although the latter show no tendency to cluster.

A few case series reported the use of EVCM for control-

ling the surgical margins of SCC. Concerning the reflectance 

mode, an initial study found a positive correlation with his-

topathology in 13 out of 23 SCCs [11], whereas a sensitivity 

of 95% and a specificity of 96% for the identification of SCC 

were achieved in a second study on 10 lesions [37]. Only 

one study has been performed in the fluorescence mode, and 

eosin for cellular cytoplasm and dermis) and appears purple 

and pink [1]. In the future, digital staining could be used in 

order to change the grayscale into a color scale that mimics 

the appearance in histology [1].

Ex vivo Confocal Microscopy for the Control 
of Surgical Margins of Cutaneous Tumors

Different from MMS, EVCM enables the evaluation of the 

resection margins immediately after excision without freez-

ing the specimen, thereby reducing the investment of time 

by two-thirds [10]. To date the analysis of surgical margins 

has been carried out by cutting the deep and lateral margins 

(“Tübingen torte” [26]) and analyzing them in vertical plane, 

perpendicular to the surface of the skin, as is done in con-

ventional histology. Our group proposed an analysis of the 

entire specimen in horizontal plane, parallel to the surface 

of the skin (“en face” technique), without cutting the lateral 

and deep margins [8]. The “en face” technique provides 

images similar to in vivo reflectance confocal microscopy 

and is particularly suitable for horizontal spreading tumors 

[8]. (Figure 6).

Most of the EVCM studies were conducted on BCCs 

[3-5,7,10,27-31] (Figure 3). Subsequently, EVCM has been 

Figure  5. Ex vivo reflectance confocal microscopy examination of a skin biopsy from a plaque of Sweet’s syndrome. Dense infiltrate of 

hyper-reflective cells in the upper half of the dermis corresponding to leukocytes (red circle) and severe edema (hypo-reflective areas, green 

asterisks) of the upper dermis with strands of dermal collagen stretched across the pseudobullous spaces (yellow arrows) are visible. [Copy-

right: ©2018 Cinotti et al.]



114 Review  |  Dermatol Pract Concept 2018;8(2):8

because the endogenous autofluorescence from the dermis is 

relatively weak (Figure 3).

The reported criteria that enable identification of BCC 

islands under fluorescence confocal microscopy are [38]:

1. Demarcated fluorescent areas with a higher nuclear den-

sity than the surrounding epidermis and adnexal structures 

(nuclear crowding)

2. Peripheral palisading (peripheral polarized and aligned 

fluorescent cells)

3. Clefting (black fluorescence-free area around the 

tumor mass)

4. Nuclear pleomorphism

5. Enlarged nucleus/cytoplasm ratio

6. Modified stroma around the tumor (more densely nucle-

ated dermis with fluorescent dots within a black back-

ground, corresponding to inflammatory cells and activated 

fibroblasts)

BCC subtypes can also be identified [7]. In superficial 

BCC tumor islands are connected to the epidermis and sepa-

rated from the dermis by some clefts (Figure 3). In nodular 

EVCM agreed with histopathology in 41 out of 43 mosaics 

obtained from 34 tumor margins of 13 SCCs [32].

False negative results can be caused by incorrect imaging 

of the sample due to the presence of artifacts [32] and the 

inability to properly flatten the fresh tissue [9]. Moreover, 

a discrepancy with histology can arise when preparing the 

specimen for standard histological examination and lateral 

slices are removed from the paraffin-embedded specimen 

before obtaining definitive sections. The material that is 

removed could contain tumor tissue seen under EVCM and 

not under histology.

Basal Cell Carcinoma

In reflectance mode, large BCCs are easily detected [8]. 

However, tiny strands of micronodular infiltrating BCCs 

could remain hidden because of the hyper-reflectivity of the 

surrounding normal dermis [10].

In fluorescence mode with a contrast agent that stains 

nuclei, such as acridine orange, BCC islands are highly fluo-

resecent and are distinguishable from the surrounding tissue 

Figure 6. Superficial basal cell carcinoma of the eyelid under ex vivo reflectance confocal microscope and horizontal section. Tumor islands 

(blue circles) are hyper-reflective and separated from the stroma by clefting. [Copyright: ©2018 Cinotti et al.]



Review  |  Dermatol Pract Concept 2018;8(2):8 115

packed and irregularly distributed nuclei [11,37]. In situ SCC 

is more difficult to identify because of the difficulty of accu-

rately detecting dyskeratotic cells and nuclear atypia [11,37]. 

Improved quality of images has been obtained by using acri-

dine orange as fluorochrome [14,32]. A study of 13 SCCs 

demonstrated that EVCM with the fluorescence mode could 

also be used to grade this tumor [32]. A well-defined tumor 

silhouette, numerous keratin pearls, keratin formation, and 

BCC tumor islands are larger and disconnected from the 

epidermis. In micronodular BCC tumor islands are smaller, 

and in infiltrative BCC tumor islands are small, elongated, 

and deep located.

Squamous Cell Carcinoma

Using the reflectance mode, squamous cell carcinomas (SCC) 

can be identified by the presence of keratinocytes with densely 

Figure 7. Clinical (a) and ex vivo reflectance confocal microscopy (b, c) aspects of melanoma. Melanoma thickness is marked by the red line 

(c) and melanoma nests (b, inset in c marked by the blue rectangle) are very easily recognizable because of their brightness (hyper-reflectivity). 

[Copyright: ©2018 Cinotti et al.]



116 Review  |  Dermatol Pract Concept 2018;8(2):8

of six melanomas with similar features to in vivo reflectance 

confocal microscopy [6]. A pilot study on 10 melanomas sug-

gested that EVCM could also be used to measure melanoma 

thickness [34] (Figure 7) with the possible future benefit of 

being able to choose the correct size of the surgical margins 

before the surgical excision.

Ex vivo Confocal Microscopy and Nails

EVCM could be particularly useful for nail tumors in order to 

confirm intraoperatively the diagnosis of the biopsy specimen 

and to proceed to the final excision without waiting for the 

histological examination. Notably, EVCM is more suitable 

than the optical examination of frozen sections of this site 

because nail tumors are often very small in size, and it is desir-

able that no material be wasted in producing sections that 

subsequently cannot be submitted to conventional pathology.

In a pilot study on six malignant epithelial tumors of the 

nail apparatus, Debarbieux et al [16] showed that EVCM in 

fluorescence mode could be a useful tool for the diagnosis 

scarce nuclear pleomorphism correlate with the diagnosis 

of well-differentiated SCC. Conversely, an ill-defined tumor 

silhouette, paucity or absence of keratin pearls, and marked 

nuclear pleomorphism is observed in poorly differentiated 

tumors. SCCs that are moderately differentiated reveal an 

intermediate pattern of growth with the presence of keratin 

formation.

Syringomatous Carcinoma

EVCM in the fluorescent mode with acridine orange has been 

performed in only two syringomatous carcinomas [33]. They 

appeared as highly fluorescent neoplastic cords of monomor-

phous cells in the dermis.

Melanoma

Recently, melanoma has been imaged by EVCM [6,17,34]. 

Proliferation of atypical melanocytes in the epidermis and 

consumption of the epidermis and nests of atypical melano-

cytes in the dermis were observed under EVCM in a study 

Figure 8. Clinical (a), fluorescence (b), and reflectance (c) ex vivo reflectance confocal microscopy aspect of Paget’s disease. Paget’s cells in 

the epidermis (red bracket; stratum corneum is marked by orange star) are visualized better (b, pink arrows) under fluorescence mode with 

acridine orange than under reflectance mode when comparing images from the same area. [Copyright: ©2018 Cinotti et al.]



Review  |  Dermatol Pract Concept 2018;8(2):8 117

tamination because the examination is made concomitantly, 

just after the specimen collection [22]. EVCM has the great 

advantage over conventional microscopy in that the sample 

is left intact with the subsequent possibility of localizing the 

infectious agent directly in the whole tissue. This could be 

particularly useful for the fast and precise identification of 

a fungus in a case of a deep fungal infection such as mucor-

mycosis [22]. To date there is only one study that compares 

EVCM to conventional microscopy and fungal culture for the 

identification of dermatophytes, and this study includes only 

three cases of hair infection [16].

As in vivo confocal microscopy, EVCM can show viral 

cytopathic effect [20,31]. EVCM has also been used success-

fully in fluorescence mode with anti-herpes virus simplex 1 

(HSV1) antibodies coupled with fluorescein isothiocyanate 

for the identification of HSV1 from the roof of six vesicles 

from three different patients [20]. This application is an 

example of how this device has the potential to identify any 

pathogen disposing of specific antibodies conjugated with 

any fluorescent agent that can be excited by a wavelength 

of 488 nm or 658 nm. Studies of comparison with standard 

methods such as Tzanck-test, histopathology, or PCR for HSV 

infection should be performed.

Conclusions

In conclusion, EVCM is a relatively new imaging technique 

that can analyze whole skin samples of up to 2 cm in diameter 

without the need to cut it into thin sections. Data for clinical 

use of EVCM is only available for the intraoperative control 

of tumor margins in BCC. However, many other tumors are 

in the evaluation phase, as well as non-tumor diseases such as 

skin infections. In the future, EVCM could be used in order 

to quickly obtain architectural and cytological details of any 

skin sample to orient the clinical diagnosis before definitive 

histological examination. A promising field seems to be the 

intraoperative nail evaluation, and a new domain that could 

be explored is hair shaft examination. At the present time, the 

main limitation of this technique is the high cost of the device, 

which limits its widespread use.

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EVCM in reflectance mode has been used to identify the 

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