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Original research
Accuracy of periocular lesion assessment using telemedicine
  1. Swan Kang1,
  2. Mohammad Dehabadi1,
  3. Dawn A Sim2,
  4. Peter B M Thomas2,
  5. Doris Appiah Ewusi1 and
  6. Daniel Ezra1
  1. 1Adnexal Department, Moorfields Eye Hospital NHS Foundation Trust, London, UK
  2. 2NIHR Biomedical Research Centre for Ophthalmology, Moorfields Eye Hospital NHS Foundation Trust and UCL Institute of Ophthalmology, London, UK
  1. Correspondence to Dr Swan Kang; swan.kang1{at}nhs.net

Abstract

Objectives To assess the agreement in diagnosis and management plans reached between clinicians reviewing eyelid lesions remotely and in face-to-face clinics.

Methods In this single-centre observational case series, data were prospectively collected on 50 consecutive adults referred with eyelid lesions suitable to be seen by a nurse. A proforma was completed to gather salient information. A nurse specialist saw patients in face-to-face clinics and collected information using the proforma, devising a diagnosis and management plan. Photographs of the eyelid lesions were taken by a medical photographer. A subsequent remote review was completed by an oculoplastic consultant using the proforma information and photographs in the absence of the patient. The diagnosis and management plan constructed by the nurse specialist were compared with those reached by the consultant.

Results Complete data were available for 44 consecutive cases. There was an overall 91% agreement (40 cases out of 44) between the diagnoses reached by the nurse specialist, and the remote reviewer; kappa coefficient 0.88 (95% CI 0.76 to 0.99). There was an overall 82% agreement (36 out of 44 cases) in the management plans devised by the nurse-led clinic and remote reviewer; kappa coefficient 0.74 (95% CI 0.58 to 0.90). The average time taken for a remote reviewer to reach a diagnosis and management plan was 1 min and 20 s.

Conclusions This study evaluated the feasibility of assessing eyelid lesions using asynchronous telemedicine. There was overall a high rate of concordance in the diagnosis reached, and management devised between the clinic and remote review.

  • information systems
  • health care
  • medical informatics
  • patient care
http://creativecommons.org/licenses/by-nc/4.0/

This is an open access article distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited, appropriate credit is given, any changes made indicated, and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/.

https://doi.org/10.1136/bmjhci-2020-100287

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    Summary

    What is already known?

    • The evidence base for the use of telemedicine in oculoplastics is limited.

    • Telemedicine provides benefits such as improved outcomes, efficiency and access to healthcare.

    What does this paper add?

    • Eyelid lesion assessment using store-and-forward telemedicine is comparable to face-to-face evaluation.

    • Remote eyelid lesion assessment can be used to optimise patient care pathways.

    Introduction

    Telemedicine is the use of electronic information and communication technologies to deliver healthcare services at a distance1 and is well established in ophthalmology, particularly in the subspecialty areas of medical retina and glaucoma.2–5 Prior to the COVID-19 pandemic, the reported applications of telemedicine in oculoplastics were largely limited to settings where the access to healthcare remains a challenge6–9 and only few studies evaluated the utility of synchronous telemedicine in assessment of oculoplastic conditions.10–12 Since the emergence of COVID-19, the use of telemedicine, particularly video consultations, has increased exponentially. The literature reports varying degree of effectiveness of video consultations in assessment of eyelid lesions.13 14 While the evidence base for the use of video consultations in oculoplastics is growing following the COVID-19 outbreak, the literature on the application of asynchronous or store-and-forward telemedicine in the assessment of eyelid lesions remains scarce.15 16 This contrasts significantly with the successful implementation and scaling of a closely related specialty—teledermatology, which has matured over two decades and is now a widely accepted form of service delivery.17

    The hospital eye service is experiencing a severe shortage of resources to safely cope with demand and it is predicted that the demand will increase by 30%–40% over the next 20 years.18 In our oculoplastic service patients with eyelid lesions make up more than 50% of new referrals. Optimising pathways for these patients is vital to provide an efficient service and to reduce waiting times particularly when identification of malignant lesions is time sensitive. Multiple initiatives have been implemented to offer prompt diagnosis and treatment of eyelid lesions. A nurse-led eyelid lesions service has been shown to provide comparable diagnostic accuracy compared with a doctor-led service.19 One-stop minor surgery lists have been set up in order to provide patients with same day surgery to expedite the delivery of their treatment and to reduce the need for multiple hospital visits. The National Health Service (NHS) long-term plan and NHS England service transformation plans for ophthalmology suggest remote care as a means to cope with a surge in patient demand.20 21 The recent pandemic along with the increasing access and use of the internet and digital technology as well as growing acceptance of remote care among clinicians and patients have accelerated the move towards telemedicine.

    We investigated the use of asynchronous telemedicine to remotely diagnose and formulate management plans for eyelid lesions. To enhance the diagnostic accuracy of such an approach, templates for structured and pertinent data collection including patient history, along with photographs of eyelid lesions were designed and used. The data and photographs were reviewed by a clinician in the absence of the patient. The agreement between the diagnosis and management plan reached by clinician reviewing the data remotely with those devised by clinician reviewing patients in face-to-face clinics was assessed.

    Methods

    This was a single-centre prospective observational case series conducted in a tertiary ophthalmic specialist hospital. Verbal consent was obtained from study participants.

    Fifty consecutive adult patients, who were referred with benign eyelid lesions based on the information provided by the referrer, were included in the study. We excluded suspected skin cancer referrals. Data were prospectively collected on patients seen between November 2019 to January 2020 in nurse-led clinics as benign eyelid lesion cases are seen in nurse-led clinics at our institution. A bespoke structured proforma was designed to characterise the eyelid lesions and gather relevant information including history of skin lesions, ophthalmic, medical and drug history (online supplemental material). A nurse specialist saw patients in face-to-face clinics and collected information using the proforma and devised a diagnosis and management plan. Photographs of the eyelid lesions were taken at the end of the clinic appointment by a qualified medical photographer using a Canon EOS 7D camera with 5184×3456 pixels resolution. A subsequent remote review of collected data and photographs was completed by an oculoplastic consultant in the absence of the patient. All cases were assessed by the same nurse specialist and the same consultant remote reviewer. Data, including patient demographics, number of days patients waited between the date of referral and the review, time taken for the consultant to review the cases remotely and referral sources as well as histopathological diagnoses where available, were collected. The diagnosis and management plan constructed by the nurse specialist in the face-to-face clinic and those reached by the consultant via remote review were compared by an independent assessor (oculoplastic fellow).

    Supplemental material

    Kappa coefficient and 95% CIs were used to evaluate the agreement between the face-to-face clinic and remote review. Pearson’s χ2 test was used compare the distribution of outcomes. Tests with p values less than 0.05 were considered statistically significant. Data analysis was performed using R software (R Core Team, 2017).

    Results

    Complete data were available for 44 consecutive cases. Six cases were excluded from the study as these patients did not wait to have their photographs taken after the face-to-face consultations, thus not allowing remote review to take place. The details of the excluded cases are listed in table 1. No case was excluded due to the insufficient photograph quality.

    View this table:
    Table 1

    Diagnoses and management plans of the excluded cases

    The mean age of patients reviewed was 47.3 years (range:18 to 72 years). Twenty-seven (61.4%) patients were female, and 17 (38.6%) patients were male. Patients waited an average of 49 days (range: 18–97) from the date of referral to be seen in the face-to-face clinic. Twenty-eight (64%) patients were referred by general practitioners while 12 (27%) were by ophthalmologists who do not specialise in oculoplastics, and 4 (9%) by optometrists. An average time taken to review a case remotely by means of assessing the collected data and photographs was measured to be 1 min 20 s (range: 20–120 s). The baseline characteristics and key metrics are summarised in table 2.

    View this table:
    Table 2

    Baseline characteristics of the study participants and key metrics

    The primary diagnoses were (as per the standard outpatient care, face-to-face clinic): chalazion n=19 (43.2%), epidermoid cyst n=9 (20.5%), papilloma n=9 (20.5%), hidrocystoma n=2 (4.5%), naevus n=2 (4.5%), xanthelasma n=1 (2.3%), conjunctival granuloma n=1 (2.3%) and lipoma n=1 (2.3%). The outcomes of face-to-face clinic were discharge n=19 (43.2%), incision and curettage n=13 (29.5%), excision biopsy n=7 (15.9%) and follow-up n=5 (11.4%). The outcomes of remote review were discharge n=17 (38.6%), incision and curettage n=14 (31.8%), excision biopsy n=11 (25%) and follow-up n=2 (4.5%) (table 3). There was no statistically significant difference between the distribution of outcomes between face-to-face and remote review (p=0.21).

    View this table:
    Table 3

    Outcomes of face-to-face clinic and remote review

    The full list of cases where there were disagreements of diagnosis and/or management plan between those reached by the face-to-face clinician and the remote reviewer is outlined in table 4.

    View this table:
    Table 4

    List of cases where there were disagreements of diagnosis and management plan between those reached by the face-to-face clinician and the remote reviewer

    There was an overall 91% agreement (40 cases out of 44) between the diagnoses made by the nurse specialist, and the remote reviewer. Kappa coefficient for diagnostic agreement between face-to-face and remote review was 0.88 (95% CI 0.76 to 0.99). Three out of the four cases with disagreements in diagnosis resulted in different management plans. In one case (case 5 of table 4; hereinafter all numerical case numbers refer to those listed in table 4), the nurse specialist diagnosed the lesion as a benign cyst and discharged the patient whereas the remote reviewer suspected a basal cell carcinoma due to the presence of central ulceration and listed for a biopsy. The lesion subsequently spontaneously resolved without intervention indicating that the lesion was of benign origin. In two cases, the lesions (a chalazion and a lipoma, cases 3 and 9, respectively) were not demonstrated well on photographs as these were subcutaneous, the undulation caused by the lesions was subtle, and there were no overlying skin changes. The lesions in question were not the focal point in the photographs probably due to the photographer being uncertain of the location of the lesions of concern. In case 3, the remote reviewer diagnosed an enlarged caruncle, where the patient was referred with a small chalazion in the lower lid near the punctum which did not display well in the photographs. The remote reviewer listed the patient for a biopsy of the caruncle whereas the nurse booked the patient for an incision and curettage of the chalazion. In case 9, the remote reviewer noted and diagnosed a papilloma which was adjacent to the lipoma and listed for a biopsy whereas the nurse practitioner brought the patient back for a review of the suspected lipoma. In case 4, a diagnosis of an epidermoid cyst was made by the nurse specialist whereas the remote reviewer diagnosed it as a chalazion and despite the discrepancy in the diagnosis, both the nurse practitioner and the remote reviewer discharged the patient.

    There was an overall 82% agreement (36 out of 44 cases) in the management plans devised by the nurse-led clinic and remote reviewer. Kappa coefficient for management agreement between face-to-face and remote review was 0.74 (95% CI 0.58 to 0.90). In two cases of chalazia (cases 1 and 2), the remote reviewer chose to list for an incision and curettage whereas the nurse specialist discharged the patients. In two cases of papilloma (cases 5 and 6), the remote reviewer either discharged the patient or listed for excision biopsy, however, the nurse specialist booked follow-up appointments in 3 months. In the case of a naevus (case 8), the remote reviewer opted for a biopsy whereas the nurse specialist arranged a follow-up appointment in a clinic.

    Seven patients were listed for excision biopsy by the face-to-face clinician and histopathological diagnoses were available for six as one patient did not contact the hospital to arrange a date for surgery. In five cases, clinical diagnose reached by both face-to-face and remote reviewers were in agreement and were confirmed by histopathological diagnoses. In one case, both face-to-face and remote reviewers diagnosed the lesion as a papilloma and the histological diagnosis demonstrated a benign intradermal naevus (table 5).

    View this table:
    Table 5

    Clinical diagnoses reached by face-to-face clinician and remote reviewer where histopathological diagnoses were available

    Discussion

    The benefits of telemedicine including improved outcomes, cost and time-efficiency, and increasing access to healthcare are well documented in ophthalmology.22–24 Telemedicine played a vital role in allowing continued provision of patient care while mitigating the risk of viral transmission during the recent COVID-19 pandemic and it has accelerated rapid integration of remote care into routine clinical practice. Oculoplastics is particularly well suited to telemedicine due to the highly visual nature of clinical assessment which can be evaluated without the need of a specialist equipment, however, the evidence base to support wider application of telemedicine is limited.13

    Our study assessed the ability to establish accurate diagnoses and management plans of eyelid lesions remotely using a data collection proforma and photographs. Diagnostic and management plan agreements were good between face-to-face consultations and remote review at 91% and 82%, respectively. Histopathological diagnoses, where available, were compared with clinical impressions made by face-to-face assessor and remote reviewer. Both face-to-face assessor and remote reviewer correctly diagnosed eyelid lesions in five out of six cases (83.3%) with both clinicians diagnosing the same lesion as a papilloma where the histopathology demonstrated a benign intradermal naevus. It is possible that the diagnostic discrepancy demonstrated in our study is not indicative of the disagreements between different modes of review but rather represents the diagnostic inaccuracies that would be observed in face-to-face clinic settings. Previous studies reported the diagnostic accuracy of 70%–96%.25–28 It has therefore been recommended that all excised eyelid tissues should be sent for histopathological analysis as clinical assessment alone will not warrant accurate diagnosis and malignant eyelid lesions may masquerade as clinically benign conditions. It is not uncommon to observe a diversity of clinical opinion among oculoplastic clinicians on the optimal management options for individual patients. In our study, although not statistically significant, the remote reviewer had a lower threshold to opt for excision biopsy whereas the face-to-face clinician was more likely to adopt a ‘wait and see’ approach. In one case, the remote reviewer suspected a basal cell carcinoma and chose to list the patient for a biopsy taking a more cautious approach.

    Although the evaluation of eyelid lesions is akin to that of skin lesions, the inherent two-dimensional character of photographic evaluation poses particular challenges for eyelid lesions. The multilamellar anatomical construction of the eyelids means that the lesions can originate from or extend to deeper anatomical structures such as the tarsus or conjunctiva and may not be demonstrated well on photographs. Furthermore, eyelid lesions are likely to be smaller than those found on other parts of the body and may require more specialised lenses for adequate image resolution. A dynamic examination of eyelid lesions provides additional information as it is possible to ascertain, for example, if the lesion is tethered to the underlying structure, which is likely to narrow down the differential diagnoses.

    Our study is one of the few that examined the utility of asynchronous telemedicine in oculoplastics. The proforma used in this study has been specifically designed to collect pertinent information to risk stratify the eyelid lesions by incorporating non-genetic risk factors such as age, history of previous skin malignancies and drug history.29–33

    Our study has several limitations. A small number of patients at a single centre with a limited range of diagnoses was enrolled and suspected malignant cases were excluded, thus limiting generalisability of the study. Six cases were excluded as clinical photographs were not captured. The face-to-face evaluation was performed by a nurse while the remote review was conducted by a doctor. The discrepancy between face-to-face consultations and remote review could be attributed to the inherent difference in training received. Having more than one face-to-face and remote reviewers and assessing intraobserver and interobserver agreement would have allowed more in-depth exploration and reduce bias. In some cases, the lesion in question was not the focal point of some clinical photographs and this made it difficult for the remote assessor to evaluate the case.

    The use of telemedicine in eyelid lesion assessment has a potential to reduce outpatient appointment and surgery waiting times, permit more accurate triaging of eyelid lesion cases, obviate the need for face-to-face appointments, and allow enhanced monitoring of eyelid lesions. This approach can be adopted for (1) referral refinement which has been shown to successfully reduce unnecessary or inappropriate referrals thus reducing waiting times; (2) image-based triage to risk stratify patients to allow more accurate assessment of the clinical urgency; (3) electronic consultation where the remote assessment can obviate the need for face-to-face appointments and (4) remote monitoring of eyelid lesions where photograph-based measurement has been shown to be more accurate than traditional face-to-face clinical evaluation.34–37

    A multicentre study including more subjects with a wider range of pathologies and histopathological diagnoses needs to be performed to further assess the accuracy of the use of asynchronous eyelid lesion assessment and to evaluate generalisability of the results. Involving more than one face-to-face and remote reviewers is important to minimise bias. Further research into patients’ and clinicians’ views on the use of telemedicine in oculoplastics should be carried out in order to design a service that addresses their needs and concerns.

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    Supplementary materials

    • Supplementary Data

      This web only file has been produced by the BMJ Publishing Group from an electronic file supplied by the author(s) and has not been edited for content.

    • Supplementary Data

      This web only file has been produced by the BMJ Publishing Group from an electronic file supplied by the author(s) and has not been edited for content.

    Footnotes

    • Twitter @dawnasim, @pbmthomas

    • Contributors Initials of the authors involved in each of the following step of writing this paper are listed below. Planning: SK, MD, DAS, PBMT, DAE; conducting: SK, MD, DAE, DE; reporting: SK, MD, PBMT, DAS, DE; guarantor: SK.

    • Funding The publication costs of this article has been enabled by a grant from Moorfields Eye Charity (GR001325).

    • Competing interests None declared.

    • Patient consent for publication Not required.

    • Ethics approval The study was performed in full compliance with the Declaration of Helsinki. Permission to perform this study was granted by Moorfields Eye Hospital NHS Foundation Trust (reference number: CA/AD/675).

    • Provenance and peer review Not commissioned; externally peer reviewed.

    • Data availability statement Data are available on reasonable request.

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