Discussion

The telescopic referral pathway in place at our unit is the first of its kind in the UK to remotely triage, assess and manage two-week-wait suspected head and neck cancer referrals.^{Reference Metcalfe, Dogan, Glazzard, Ross and George3} Our early data demonstrated that this pathway is safe for patients and may lead to numerous benefits for the service, most notably in terms of providing flexible clinic capacity and optimising consultant time. We are now able to present data on 660 patients who have passed through the low-risk arm of this pathway, with a mean follow up of 14 months.

Head and neck cancer is the eighth most common cancer site in the UK and the number of new cases on average each year is projected to rise from around 14,000 in 2023–2025 to around 16,300 in 2038–2040.⁵ It is well established that the sensitivity of a suspected cancer pathway must be high to ensure cancers are not missed; indeed, the cancer conversion rate for head and neck cancers in the UK is in the region of 5 per cent.^{Reference Mettias, Charlton and Ashokkumar6} However, with increasing referral numbers, the 95 per cent of patients referred who do not have cancer place a significant burden on pathway capacity. As such, the concept of triaging has emerged to facilitate the identification and prioritisation of high-risk patients. Further impetus for this concept was provided by the Covid-19 pandemic.

Hardman et al.^{Reference Hardman, Tikka and Paleri7} have presented data for over 4500 patients who underwent telephone triaging using the widely validated risk calculator adopted by our pathway, demonstrating a low risk of harm. Our pathway aims to further streamline the two-week-wait process by managing all low-risk referrals via a nurse-led clinic, with consultant review of remotely acquired images.

Our intial pilot data suggested that the described pathway was safe, but the above data collected over a two-year period gives a more robust insight into both the safety of the pathway and expected clinical outcomes. The overall cancer conversion rate in our low-risk patients of 0.9 per cent is consistent with the conversion rate observed in our pilot data (<1 per cent)^{Reference Metcalfe, Dogan, Glazzard, Ross and George3} and data from Hardman et al., who showed that the negative predictive value of a low-risk outcome from the calculator was 99.1 per cent.^{Reference Hardman, Tikka and Paleri7}

Whilst cancer incidence was low, incorporating remote examination by a consultant head and neck surgeon allowed us to detect six head and neck cancers that may have been missed had care been deferred based on the triage outcome alone. Two of these patients were notably young compared with the typical demographic, at 30 and 36 years.

Potential limitations in the triage process were highlighted by the patient diagnosed with a T4N0M0 supraglottic cancer, who was triaged as low risk based on the written referral from the general practitioner, but when re-scored face-to-face by the nurse practitioner was found to be high risk. Despite this, remote examination allowed a prompt diagnosis and the patient remains in remission following chemoradiotherapy.

As an exclusively low-risk cohort, our patient demographics inversely mirror what would traditionally be expected in patients with a head and neck cancer diagnosis, namely a preponderance of females compared with males (82 vs 18 per cent) and a relatively young mean age of 58 years. The need for subsequent investigation in just over a third of patients is in keeping with what would be expected on a standard two-week-wait pathway for head and neck cancer.⁸ Senstivity is a key parameter for such a pathway and the current data suggest there have been no missed head and neck cancers.

It should be acknowledged that only four months have passed between the most recent patients passing through the pathway and data analysis, meaning further re-referrals could emerge over the coming months. Data collection is ongoing to ensure these would be detected.

Overall, the re-referral rate was low (3.2 per cent) and looking back at the two serious diagnoses made at re-referral (oesophageal cancer and motor neurone disease), it was difficult to see how an earlier diagnosis could have been made on a traditional face-to-face pathway. In oesophageal cancer case, five months passed between the initial referral and re-referral, and an oesophagogastroduodenoscopy in this time did not make a diagnosis. The nasendoscopic images from the initial assessment were also reviewed in light of the diagnosis, but no abnormality was seen. This perhaps illustrates another potential advantage of this pathway from a documentation perspective, that all captured images are stored on the patient records system.

The Faster Diagnosis Standard was introduced in April 2020 to ensure that all patients who are referred for the investigation of suspected cancer find out within 28 days if they do or do not have a cancer diagnosis. Moving forward, this is one of the key standards against which a cancer pathway is assessed. Overall, our mean time to a patient being informed whether they did or did not have cancer fell close to this (28.6 days), but there was significant variation (range, 2–276 days).

The pathway utilises text messages as the default communication method to patients. The instant nature of text messages coupled with the short mean time between nurse practitioner review and consultant report (one day) assists with adherence to the Faster Diagnosis Standard and means, for those discharged following initial review, the limiting step was clinic capacity, where patients waited three weeks on average for review.

For patients requiring subsequent investigation, adherence to the Faster Diagnosis Standard becomes increasingly challenging, but there are numerous factors at play. Indeed, for patients with the longest time to Faster Diagnosis Standard, non-attendance at appointments was a key issue. Clearly this is an area that needs to be optimised moving forward; options may include expansion of the low-risk pathway to increase clinic capacity and provide a more timely initial review.

Our data demonstrate that a combination of risk stratification and asynchronous telescopic assessment facilitates management of suspected head and neck cancer referrals and many of the concepts incorporated is likely to become more prevalent in the specialty moving forward. The EVEREST-HN research programme is already underway and looks to utilise ‘big data’ to refine the triage process further to identify high-risk patients for targeted investigation prior to their hospital appointment.⁸ It will also serve to reassure the worried well sooner.

Interesting work is emerging on the use of artificial intelligence (AI) to augment the triage process whereby patients are triaged via automated voice recognition,⁹ which may have benefits in terms of staff utilisation and reducing human errors. However, no data have yet been published. AI may also have potential for the detection of early-stage laryngeal cancer based on endoscopically acquired images.^{Reference Mahmood, Shaban, Rajpoot and Khurram10} The use of other diagnostic adjuncts, such as narrow band imaging, may also enhance a remote assessment pathway as their application becomes more widespread.

While our pathway includes a trained nurse practitioner to examine patients, the use of senior speech and language therapists as part of a similar pathway has also been reported. Butler et al.^{Reference Butler, Sellstrom, Eastwood, Hamilton and O'Hara11} have published data from a speech and language therapist-led two-week-wait clinic that has the advantage of employing speech and language therapist expertise to provide a therapeutic service to patients with voice symptoms in addition to the primary aim of cancer detection. Whilst the speech and language therapist team operate with some autonomy, the care of all patients in this study was overseen by a consultant head and neck surgeon, as is the case with our model.