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Journal of Primary Health Care Journal of Primary Health Care Society
Journal of The Royal New Zealand College of General Practitioners
RESEARCH ARTICLE (Open Access)

Excision pathways for keratinocyte cancers diagnosed by teledermatology: a retrospective review

J. P. Tirado-Perez https://orcid.org/0009-0008-7041-2744 1 * , A. Oakley https://orcid.org/0000-0002-9461-2790 2 3 , R. Gansel https://orcid.org/0009-0009-9046-0935 2
+ Author Affiliations
- Author Affiliations

1 Dermatology Department, Virgen Macarena University Hospital, Sevilla, Spain.

2 Department of Dermatology, Te Whatu Ora Health New Zealand Waikato, Hamilton, New Zealand.

3 Department of Medicine, The University of Auckland, Auckland.

* Correspondence to: jptp0510@gmail.com

Handling Editor: Felicity Goodyear-Smith

Journal of Primary Health Care 16(1) 90-95 https://doi.org/10.1071/HC23098
Submitted: 1 September 2023  Accepted: 10 November 2023  Published: 14 December 2023

© 2024 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of The Royal New Zealand College of General Practitioners. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Introduction

The New Zealand population has one of the highest incidences of skin cancer in the world. Hospital waiting lists for surgical excision of keratinocytic skin cancers (basal cell carcinoma and squamous cell carcinoma) are lengthy, and increasingly, excisions are undertaken in primary care. Teledermatology, in response to general practitioners’ electronic referrals (e-referrals), can improve clinical communication between general practitioners and dermatologists.

Aim

The aim of this study was to evaluate an excision pathway for keratinocytic cancers diagnosed by teledermatology.

Methods

A retrospective observational descriptive review of a 3-month cohort of primary care e-referrals was undertaken.

Results

Three hundred and fifty eight suspected keratinocytic cancers (KCs) were diagnosed by teledermatology; histology reports confirmed KC in 201 of 267 excisions (75%). The majority (77.2%) were excised by general practitioners an average of 25 days after the dermatologist’s recommendation. The rest were excised by plastic surgeons in private (3.4%) or at a public hospital (19.5%) after an average of 40 or 134 days, respectively.

Discussion

E-referral pathways are now widely implemented. However, the ideal workflow for skin cancer management is unknown. We have demonstrated in New Zealand that surgery can be undertaken in primary care within a month of a teledermatology diagnosis and excision recommendation.

Conclusion

This study reports prompt excision of KCs by general practitioners after an e-referral and a teledermatology response.

Keywords: basal cell carcinoma, dermatologists, general practitioners, New Zealand, primary care, referrals, Skin cancer, squamous cell carcinoma, workflow.

WHAT GAP THIS FILLS
What is already known: Keratinocytic cancers are increasing worldwide. Teledermatology is a valuable tool for communication between general practitioners, dermatologists, and plastic surgeons.
What this study adds: It describes the teledermatology diagnosis of 358 suspected keratinocytic cancers after e-referral, and pathways to excision by general practitioners, dermatologists, and plastic surgeons.

Introduction

The ‘nonmelanoma’ skin cancers are predominantly keratinocytic cancers (KCs): basal cell carcinoma (BCC) and cutaneous squamous cell carcinoma (SCC). With an increasingly aged and sun-damaged population, excision of these tumours increases the burden on hospital surgical services. In Aotearoa New Zealand (NZ), more than 70 000 individuals were estimated to have been diagnosed with invasive KC in 2013, and 80 000 people were expected to be diagnosed in 2018 when the population was 4.9 million.1 More than one-third of patients with KC will develop at least one other KC over their lifetime.2 Diagnosis, treatment, and follow-up of KC are costly to the individual and public and private health services. The healthcare costs for new patients presenting with KCs were estimated to be NZ$ 129.4 in 2021.3

Several approaches to publicly funded skin cancer surgery in primary care have been initiated in NZ.47 E-referrals and teledermatology responses showed improved timeliness for melanoma surgery in primary care compared to hospital services in the Waikato.4 The Canterbury Initiative increased skin cancer surgery in primary care with a coordinated approach, including practical training, HealthPathways guidelines and e-referrals, and funding.5 A teledermoscopy service supports Waitematā’s e-referrals for suspected skin cancers, and many lesions are triaged to specialist-trained GPs for excision.6,7 Pathways to skin cancer diagnosis and management vary throughout NZ; Te Whata Ora does not employ dermatologists or plastic surgeons in all districts, and the training and surgical skills in primary care vary.

Teledermatology is also internationally recognised as an important form of healthcare delivery for diagnosing skin cancers.8,9

In the Waikato district, general practitioners (GPs) can refer patients with lesions suspicious of skin cancer to Dermatology for advice via a Suspected Skin Cancer pathway.4 During 2022, an average of 345 e-referrals were received each month for one to five specified lesions. Completing a lesion-specific template and attaching regional, close-up, and dermoscopic images are mandatory. The dermatologist responds with advice and treatment recommendations for each lesion. The main treatment for KC is complete surgical excision. 10 In NZ, GPs may undertake the surgery or refer to a plastic surgeon, dermatologist, or other specialist in a public hospital (where treatment for accepted patients is free) or in a private setting (insurance or self-funded).

This study’s primary objective was to determine the local excision pathways for KCs diagnosed by teledermatology after e-referral. The secondary objective was to determine how many suspected KCs were excised after a dermatological recommendation, by whom, and how long patients waited for their initial surgical procedure.

Methods

The study was registered with the local Clinical Audit Support Unit (4382P). It was a retrospective observational descriptive evaluation of primary care e-referrals received in one health district from 1 March 2022 to 31 May 2022 coded C449 (ICD-10 AM) by one of four teledermatologists. For each e-referral, we identified lesions diagnosed as KC and excluded non-KC.

We recorded demographic data (gender, age, ethnicity), the number of KCs per e-referral, clinical data (lesion location, referrer’s diagnosis, dermatologist’s diagnosis, and treatment recommendation), and the average response time. Using the hospital’s and private laboratory’s electronic records, we found the date of excision, histological report (histological diagnosis, completeness of excision and distance from the lateral and deep excision border to the tumour), and the identity of the surgeon.

Data were collected using a Microsoft Excel spreadsheet for descriptive statistical analysis. An ethics review is not required in NZ for a clinical audit.

Results

Demographic data (Table 1) were determined from all e-referrals coded as C449, which included 322 patients with an average age of 72.5 years (31–99); 45.03% were female with an average age of 73.7 years and 54.97% were male with an average age of 72.0 years. Ethnicity was most often recorded as NZ European (88.20%), other European (7.14%), or Māori (2.80%). The e-referrals recorded that 44.72% of patients had a history of skin cancer, more commonly in males (45.70% of males) than in females (43.50% of females). The average time for the dermatologist to respond to the referral was 13 days.

Table 1.Demographic data.

N (322)Frequency (%)Age (mean, median, range)
Sex
 Male17754.9772.0, 74, 31–94
 Female14545.0373.7, 74, 34–99
Ethnicity
 European – NZ28488.20
 European – Other237.14
 Māori – NZ92.80
 European – not further defined30.93
 Latin American/Hispanic10.31
 African10.31
 Not stated10.31
Skin cancer history
 No17855.28
 Yes14444.72

NZ, New Zealand.

Clinical data (Table 2) were determined for 358 lesions in 310 referrals after excluding incorrectly coded clinical diagnoses. Body location was selected using a drop-down menu, most often head and neck (36.59%), arm and hand (20.39%), or lower leg and foot (15.36%) and less often on the torso, back, thigh, and buttock. Lesions on the head and neck were most often on the nose, followed by the neck, mandibular area, forehead, ear, and scalp.

Table 2.Lesion data.

N (358)Frequency (%)
Location of lesion
 Head and neck13136.59
 Arm and hand7320.39
 Lower leg foot5515.36
 Back4312.01
 Torso3810.61
 Thigh and buttock185.03
Referrer’s diagnosis
 SCC16546.09
 BCC14540.50
 Unknown267.26
 Seborrhoeic keratosis61.68
 Other61.68
 Melanocytic naevus51.40
 Melanoma41.12
 Bowen disease10.28
Dermatologist’s diagnosis
 SCC16546.09
 BCC15844.13
 Keratinocytic skin cancer359.78
Dermatologist recommendation
 Excision35097.8
 Topical treatment30.84
 Biopsy or monitor20.56
 Biopsy10.28
 Cryosurgery or topical treatment10.28
 Radiotherapy or monitor10.28

SCC, squamous cell carcinoma; BCC, basal cell carcinoma.

The referrer diagnosis was most often SCC (46.09%) or BCC (40.50%). Other suspected diagnoses included seborrhoeic keratosis, melanoma, melanocytic naevus, SCC in situ, wart, unknown, or other. The dermatologist diagnosed SCC (46.09%), BCC (44.13%), or keratinocytic skin cancer (9.78%) when either SCC or BCC was likely. Diagnostic concordance between referrer and dermatologist was 73.9% for SCC and 67.0% for BCC.

Excision was recommended for 350 lesions (97.8%) in 302 patients. Other treatment suggestions were to monitor, topical treatment (usually imiquimod), incisional biopsy, radiotherapy, and cryosurgery. The flowchart (Fig. 1) demonstrates the pathway and timeliness of the lesions. A total of 267 excisions were completed, while 83 excisions were not carried out (Supplementary Table S5). Most excisions were performed by GPs (77.15%) after an average of 25.2 days, excluding 20 excisions in primary care before receiving the dermatological recommendation. The rest were performed by the plastic surgical department (22.85%) in a public hospital (19.48%) or plastic surgeons in a private clinic (3.37%) after an average of 133.8 and 39.6 days, respectively. Excision specimens were analysed by a private laboratory (80.52%) or by the public hospital laboratory (19.48%) (Table 3).

Fig. 1.

Flowchart showing keratinocyte cancer excision pathways after teledermoscopy diagnosis. BCC, basal cell carcinoma; SCC, squamous cell carcinoma; KC, keratinocytic cancer.


HC23098_F1.gif
Table 3.Excision performance.

N (267)Frequency (%)Days to excision
Type of practice
 Primary care20677.1525.2
 Hospital Department of Plastic Surgery5219.48133.8
 Private plastic surgeon93.3739.6
Laboratory
 Private21580.52
 Hospital5219.48

N, number of lesions.

Histology reports of the 267 excisional biopsies included 201 KCs (75.3%): 68 SCCs and 133 BCCs (Table 4). The teledermatologist diagnosis was concordant with histology in 181 lesions (67.8%), being higher for BCC (87.9%) than SCC (48.8%) (Table 4). The distance of the tumour from the nearest resection lateral and deep border in millimetres (mm) was recorded for confirmed KCs. Details of excision margins have been previously reported.11

Table 4.Dermatological and histological diagnosis, and concordance.

Dermatological and histological diagnosisN (267)Frequency (%)Concordance (%)
Dermatologist diagnosed SCC12948.31
 SCC6323.6048.8
 BCC176.37
 Solar keratosis155.62
 Seborrhoeic keratosis72.62
In situ SCC72.62
 Epidermal inclusion cyst41.50
 Wart31.12
 Scar31.12
 Lichen planus-like keratosis20.75
 Dermatofibroma10.37
 Hyperkeratosis, chronic folliculitis10.37
 Hyperkeratosis, possible porokeratosis10.37
 Melanoma10.37
 Prurigo nodularis10.37
 Solar elastosis10.37
 Solar keratosis with lichen planus-like inflammation10.37
 Vascular malformation10.37
Dermatologist diagnosed BCC11643.45
 BCC10238.2087.9
 SCC31.12
 Dermatofibroma20.75
 No evidence of malignancy20.75
 Dermal fibrosis10.37
In situ SCC10.37
In situ SCC and seborrhoeic keratosis10.37
 Scar10.37
 Seborrhoeic keratosis10.37
 Solar keratosis10.37
 Superficial leiomyosarcoma10.37
Dermatologist diagnosed keratinocytic skin cancer228.24
 BCC145.2472.7
 Solar keratosis41.50
 SCC20.7572.7
In situ SCC20.75

N, number of lesions; SCC, squamous cell carcinoma; BCC, basal cell carcinoma.

Discussion

We have described a successful e-referral pathway in one health district between GPs and teledermatologists for managing KCs. There was diagnostic concordance between the referrer and responding dermatologist in more than two-thirds of lesions, reflecting good knowledge and skills in primary care. GPs performed most of the excisions within a month of referral. In 20 cases, this was before the response had been received, which may have been due to perceived urgency or convenience.

There is growing interest in implementing teledermatology for the diagnosis of skin cancer.12 In many reports, teledermatology has shown a higher sensitivity for cancer detection than face-to-face examination, providing high-resolution images are received, including dermoscopy images.12 Our teledermatologists’ diagnostic uncertainty was mainly due to referrer nonadherence to the e-referral requirements for regional, close-up, and dermoscopy images of high resolution (>2000 × 1500 pixels), in focus, well-lit, and with a plain background.

Three-quarters of the lesions were excised in primary care, including some high-risk lesions on the head and neck. Patients waited an average of 108 days longer to have an excision undertaken at the public hospital than in primary care. Using GP skin surgeons to excise KCs mitigates the long waitlists for hospital surgical excision. Treatment in primary care may incur costs to the patient and a higher risk of the surgery being incomplete, with our study finding that 15 of 201 KCs were incompletely excised in primary care, necessitating further treatment.11 We recommend following the minimal clinical margin guidelines of 4 mm for SCC and 3 mm for BCC.1315

An analysis of why surgery was not performed in 23.71% of lesions when recommended is out of scope for this study as we did not have access to the primary care records. Eight lesions were treated non-surgically in primary care despite the dermatologist recommending excision, and 20 lesions were excised before the recommendation was received.

Conclusion

We have described a collaborative skin cancer workflow in one health district in New Zealand using teledermatology responses to e-referrals made by general practitioners. Teledermatology is unavailable in many districts of NZ where there is no dermatologist or other expert in skin cancer diagnosis. Referrers to a teledermatology service should be provided with a template to remind them to include relevant patient risk factors and lesion characteristics. To optimise diagnostic quality, they should attach high-resolution, regional, close-up, and dermoscopy images. Excision is usually recommended for suspected KC. General practitioners play an essential role in carrying out most surgeries within a month of the recommendation. They should be trained, credentialed according to their skills, and follow surgical guidelines.

Supplementary material

Supplementary material is available online.

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