The feasibility and Acceptability of a Home-Based, Virtual Exercise Intervention for Older Patients with Hepatocellular Carcinoma: Protocol for a Non-Randomised Feasibility Study (TELEX-Liver Cancer)

DOI: https://doi.org/10.21203/rs.3.rs-966837/v1

Abstract

Background

The number of incident cases and deaths from primary liver cancer, predominantly hepatocellular carcinoma (HCC), has increased markedly in the last two decades. HCC is generally diagnosed at an advanced stage and most new cases are in people aged over 70 years with age-related comorbidities. Treatment options are often limited, with most patients receiving palliative treatment or supportive care only. As a consequence, maintaining quality of life (QoL) through symptom management is critically important and is a core objective of clinical care. Strong evidence supports the efficacy of supervised exercise training for addressing certain cancer-related symptoms, including QoL, physical function and fatigue. However, there are many barriers to implementing supervised exercise programmes within cancer care pathways, including economic pressures on healthcare systems and personal barriers for patients. Recent advances in technology allow patients to exercise at home under the ‘virtual’ supervision of an exercise professional through videoconferencing software (termed ‘Telehealth exercise’). Despite its potential, there are uncertainties relating to the feasibility, acceptability and safety of Telehealth exercise in people living with HCC.

Methods

This is a protocol for a prospective, single-centre, single-arm feasibility trial. We aim to recruit 20 patients aged 60 years or older who have received treatment for HCC and are undergoing routine clinical monitoring. Patients will be invited to take part in two online, home-based, group exercise sessions per week for 10 consecutive weeks. The ‘virtual’ exercise sessions will be delivered in real-time by an exercise professional through videoconferencing software. Each session will comprise 30-minutes of aerobic and resistance exercise performed at a moderate-intensity, as guided by the 10-point Borg rating of perceived exertion scale. Feasibility outcomes include recruitment, retention, adherence, intervention fidelity and safety. Acceptability of the intervention will be assessed using a mixed-methods approach via bi-weekly online surveys and an exit telephone interview. Physical function, accelerometry-measured physical activity, and patient-reported outcome measures (PROMS) will be assessed before and after the intervention. Physical function outcomes include the Short Physical Performance Battery, Liver Frailty Index, and mid-upper arm circumference. PROMS include the Functional Assessment of Cancer Therapy – Hepatobiliary questionnaire, Functional Assessment of Chronic Illness Therapy – Fatigue questionnaire, Activities-Specific Balance Confidence Scale, Hospital Anxiety and Depression Scale, and the Godin Leisure-Time Exercise Questionnaire.

Discussion

This mixed-methods study will address uncertainties relating to the feasibility and acceptability of delivering live, online, home-based, group exercise sessions to patients with HCC. The findings will inform whether any modifications are required to refine and optimise the intervention, and the assessment of outcome measures will provide information on the likely size and variability of intervention effects. Collectively, the data generated will inform the design of a subsequent, adequately-powered, randomised controlled trial to evaluate the efficacy of the Telehealth exercise intervention.  

Trial registration

ISRCTN14411809


Introduction

Primary liver cancer is the seventh most common cancer and third leading cause of cancer death worldwide, accounting for more than 8% of all cancer deaths [1]. Global cases of incident liver cancer and mortality are increasing. The Global Burden of Disease Study reported that from 1990 to 2017, the number of new liver cancer cases and liver cancer-related deaths have doubled [2]. In the United Kingdom (UK), liver cancer has shown the fastest rise in mortality rates for both males and females in the last decade [2]. There is also a strong relationship between liver cancer mortality and deprivation in England, as evidenced by the two-fold higher mortality rates in the most deprived areas compared with the least deprived [3].

The most common type of primary liver cancer is hepatocellular carcinoma (HCC). HCC is generally diagnosed at an advanced stage and most new cases are in people aged over 70 years with age-related comorbidities, such as frailty syndrome and sarcopenia [4, 5]. The majority of HCC patients in the UK are not eligible for curative treatment and the prognosis of HCC is typically poor, with a median survival of approximately 6 months and 5-year survival rate of less than 15% [6, 7]. HCC is commonly accompanied by undesirable symptoms, including pain and fatigue [8], which have a negative impact on functional status and quality of life (QoL) [9]. As a consequence, maintaining QoL through symptom management is critically important and often a core objective of clinical care for patients with HCC [10].

A growing body of evidence supports structured exercise as an adjunct therapy in cancer care. The American College of Sports Medicine (ACSM) Roundtable in 2018 reported that specific doses of exercise training can improve QoL, fatigue, physical function, anxiety, and depressive symptoms in people living with and beyond cancer [11]. The review also concluded that supervised exercise is more effective than strictly unsupervised programmes [11]. However, there are many barriers to successfully implementing supervised exercise programmes within cancer care pathways, including economic pressures on healthcare systems and personal barriers for patients. Inconvenient travel distances and a lack of access to appropriate facilities are key barriers to regular physical activity for cancer survivors [12, 13], and most patients prefer home-based exercise [1417]. Cancer survivors also report wanting more guidance on the type and specific characteristics of physical activity (i.e. frequency, intensity, and duration) they can safely undertake [18]. The challenge is to develop effective physical activity interventions that are accessible and sustainable and can be delivered across local healthcare providers [16].

Recent advancements in videoconferencing technology allow patients to exercise at home under the ‘virtual’ supervision of an exercise professional, termed ‘Telehealth exercise’ [19]. The exercise instructor can guide patients through the exercise in real-time, mimicking the delivery of traditional facility-based exercise training without the need for travel or access to facilities. Moreover, virtual exercise sessions can be delivered in a group-based format, which may provide a peer-supportive environment. Thus, there is potential for Telehealth exercise to optimise the health-related benefits of exercise through expert supervision, whilst also circumventing common barriers to physical activity and meeting the preferences of cancer survivors.

Despite the potential of Telehealth exercise, there are uncertainties regarding its feasibility and acceptability in people living with and beyond cancer. One recent study reported that delivering live, online, group-based exercise to highly-functioning older adults via a videoconferencing platform is safe and feasible, as evidenced by no adverse events and high adherence (90%) and satisfaction rates [20]. Another recent study reported no intervention-related adverse events and reasonable adherence (79%) to an online falls prevention programme delivered via videoconference in older adults with mild cognitive impairment [21]. However, a 2020 rapid review of Telehealth exercise interventions for cancer survivors found that no studies have used real-time videoconferencing to support the delivery of home-based exercise [22]. There are several considerations that may limit the uptake of Telehealth exercise in patients living with HCC, including the need to consistently adhere to online exercise whilst managing the fluctuating symptoms associated with chronic liver disease. Unaddressed issues relating to acceptability and feasibility of Telehealth exercise could undermine an evaluation of intervention efficacy [23]. Therefore, in line with Medical Research Council guidance on developing and evaluating complex interventions [23], this study will assess the feasibility, acceptability, and safety of delivering a 10-week Telehealth exercise intervention to older patients with HCC. The findings will inform the design of a subsequent, adequately-powered, evaluative randomised controlled trial (RCT).

Aims And Objectives

Methods

Study design

TELEX-Liver Cancer is a prospective, single-site, single-arm feasibility trial. In addition to receiving standard care, patients will receive a 10-week, home-based, virtual, group exercise intervention delivered in real-time by an experienced physiotherapist. Feasibility and acceptability of the intervention and study procedures will be assessed using a mixed-methods approach. Physical function and patient-reported outcome measures will be assessed at baseline and after the 10-week exercise intervention. A schematic diagram of the study schedule is presented in Figure 1. The study is prospectively registered on the International Standard Randomised Controlled Trial Number (ISRCTN) registry (ISRCTN14411809). A Standard Protocol Items: Recommendations for Interventional Trials (SPIRIT) checklist [24] in the supplementary files.

Study setting

Participants will be recruited from outpatient liver cancer clinics at the Liver Unit at Newcastle upon Tyne Hospitals NHS Foundation Trust (NuTH), UK. It is anticipated that patients will be recruited over a 6-month period. NuTH is the study sponsor. The virtual supervised sessions will be delivered by an NHS-employed physiotherapist and patients will complete the exercise sessions at home.

Participant eligibility

Inclusion criteria

  • Clinical diagnosis of HCC

  • Aged 60 years or older

  • Have received NHS standard treatment for HCC (determined by stage of disease), with post-treatment imaging reporting a complete response, partial response or stable disease.

  • Currently undergoing ‘active monitoring’ at NuTH, involving routine imaging scans and outpatient visits every 3-6 months

  • Childs Pugh of B7 or lower (i.e. preserved liver function)

  • World Health Organisation performance status of 0 or 1

  • Minimum life expectancy of six months

  • Willing and able to give written informed consent

Exclusion criteria

  • Aged less than 60 years

  • Uncontrolled cardiovascular or metabolic disease

  • Breathlessness at rest or with mild exertion

  • Severe resting hypertension or (≥180/100 mmHg) or tachycardia (≥100 bpm)

  • Inability to understand written and verbal instructions in English

  • Physical disability or mental impairment that precludes safe and adequate participation in the study

Patient identification and consent process

Patients will be recruited from the Liver Unit at NuTH. After receiving standard care treatment for HCC, patients typically undergo post-treatment imaging (CT or MRI scan) and attend a follow-up appointment at the specialist liver cancer clinic. The treating physician (HR) will identify potential patients ahead of the follow-up appointment by reviewing post-treatment imaging reports and medical records, which are routinely sent to her for review. HR will also review the HUNTER trial registry (ISRCTN16680540) to identify potentially eligible patients.

Patients that meet the eligibility criteria will be sent a study invitation letter and participation information sheet by mail. At the clinic visit, HR will discuss the study with eligible patients after they have received standard NHS care (i.e. review, examination, and blood tests). If the patient is interested in taking part, a research team member will provide them with more information, answer any questions about the study, obtain written informed consent, collect baseline data, and offer an induction to the intervention (either on the same day as the clinic appointment, or an alternative day if preferred by the patient).

Preparation procedures

During the intervention induction, a member of the research team will show patients how to use the Zoom videoconferencing platform (Zoom Video Communications, California, USA) on a tablet and familiarise them with the exercises and equipment to be used in the study. The researcher will initially demonstrate an exercise and then ask the patient to perform the exercise themselves, with technique adjusted if necessary. Patients will also be instructed on how to self-monitor exercise intensity using the Borg 10-point rating of perceived exertion (RPE) scale [25]. Patients will then receive an intervention pack that includes an instruction manual, exercise diary, RPE scale, incremental level resistance bands (TheraBand, Ohio, USA), pedal exerciser, and a wrist-worn accelerometer (ActiGraph GT9X Linkm, ActiGraph, LLC., Pensacola, FL). The exercise diary will be used to record daily step counts as well as the type, duration, and intensity of exercise completed each day (including the virtual exercise sessions). Patients without internet access or an appropriate internet-enabled device will be provided with a 10.1” tablet pre-loaded with the Zoom app and unlimited 4G data for the duration of the study (Samsung Galaxy Tab A7 10.4” 4G Tablet) free of charge. It will be made clear to the patient that they will not be held responsible for loss or accidental damage of any of the equipment supplied by the research team. The equipment will be handed to patients at their appointment or posted to patients (via a tracked courier/mailing system) if there are any concerns about the patient’s ability to carry the equipment home.

In addition, the researcher will schedule a 15-minute, one-on-one, online introductory session on Zoom with each patient before the intervention begins. During the introductory session to Zoom, the researcher will inspect the location of the exercise area, resolve any technical issues, and ask the patient to practice a sample of the exercises to be used in the study in order to re-assess technique and RPE, with exercises modified if required. Patients will be emailed a URL to a password-protected virtual Zoom ‘room’ ahead of their first scheduled exercise session. The same password and URL will be used for all of the exercise sessions.

Exercise intervention

Patients will be invited to take part in two, virtual exercise sessions per week for 10 weeks. Exercise sessions will comprise a maximum of 10 patients at any one time to allow for adequate safety monitoring and provision of individual feedback. Sessions will be delivered on weekdays in the late morning or early afternoon, which reflects patient preferences identified in our patient and public involvement (PPI) discussions, and also avoids early morning exercise when exercise-induced adverse cardiovascular events are more frequent [26]. Exercise sessions will be separated by at least 48 hours.

Exercise sessions will involve the option of chair-based or standing-based exercises (within the same session). Whether patients complete chair-based or standing exercises will depend on patient preference and functional ability (assessed by the research team); patients who take >15-seconds to perform five sit-to-stands at baseline, show an inability to stand for 10 seconds in side-by-side/semi-tandem/tandem on baseline balance tests, self-report falling within last 12 months, and/or score <50% on the Activities-Specific Balance Confidence Scale (ABC Scale), will be restricted to chair-based exercises in weeks 1-4 because of an increased risk of falls [27, 28]. A fall event is defined as “when you land on the floor or the ground, or fall and hit objects like stairs or pieces of furniture, by accident” [29]. If a patient expresses a preference to change to standing or seated exercises after this period, they will be re-assessed virtually and permitted to do so if they meet the requirements stated above. We will ask patients to nominate an emergency contact who we will contact if an adverse event occurs during the exercise sessions. In the case of an emergency, the research team will also contact emergency services and terminate the exercise session for all patients. Furthermore, we will encourage patients to have another person in the house when they are taking part in the scheduled exercise sessions, but if this is not possible, we will ask them to remotely ‘check-in’ with their nominated contact after completing each exercise session. Patients will be required to have their cameras turned on and be visible during the exercise sessions so that they can be monitored for potential adverse events.

Each exercise session will last 45-minutes and comprise of a 10-minute warm-up, 30-minutes of aerobic and resistance exercises, and a 5-minute cool-down involving static stretching. The exercises focus on multi-joint movements recruiting major muscle groups in the lower- and upper-body. The warm-up will involve 5-minutes of a pulse-raising activity (such as seated pedalling) and 5-minutes of joint mobility exercises. Patients will then perform two sets of four aerobic exercises and two sets of four resistance exercise in a circuit-like manner. Each exercise will be performed for 60-seconds followed by 60-seconds of rest; this length of time was chosen to provide an adequate stimulus for adaptation but also provides patients enough time to prepare for the next exercise. Aerobic exercises will include exercises such as seated pedalling, high knee marching, step-jacks, side-steps, stepping forwards/backwards, and horizontal/vertical punches. Resistance exercises will use body weight and resistance bands as resistance, and will include exercises such as chair-rises, assisted lunges, horizontal rows, upright rows, overhead presses, wall press-ups, calf raises, rotations, and bicep curls. Each exercise can be modified to be performed in either a seated or standing position. The combination and sequencing of exercises will be varied between the two weekly sessions because our PPI discussions and previous research [20] suggests that older adults taking part in online exercise prefer some level of variation. An example exercise session is presented in Figure 2.

 

The intensity of exercise will be performed at 3-5 on the Borg 10-point RPE scale, which corresponds to moderate-intensity [30] and qualitative descriptions of “moderate” to “hard” [25]. Moderate-intensity exercise has been shown to improve QoL in cancer survivors [11] and is less likely to trigger acute cardiovascular events compared with vigorous-intensity exercise [31]. The use of RPE to guide intensity ensures that the exercise intervention has inherent progression as participants become accustomed to the exercise. Each session will finish with a cool-down of static stretching held for 20-seconds each at the point of “slight discomfort” [30]. The intervention facilitator will document attendance, adverse events, and any noteworthy technical/practical issues that arise during each session. In addition, patients will wear the wrist-worn accelerometer during each session, which will provide an objective assessment of exercise intensity during the exercise sessions because the activity data are timestamped.

Other intervention components

A member of the research team will telephone patients (≈10 minutes) once every two weeks to encourage compliance and motivation, answer questions, and record any adverse events. Patients will also be able to contact a research team member via telephone or email for assistance if they experience any technical difficulties during the exercise sessions. No concomitant care or interventions will be prohibited during the trial [24].

Patients will be able to retain their resistance bands and pedal exerciser at the end of the study to allow them to continue exercising at home after the study has finished. Tablets and accelerometers will be returned to the research team at the follow-up visit to the hospital.

Outcomes

The primary outcome for this study is feasibility of the exercise intervention and study procedures. Measures of physical function and PROMs will be assessed before and after the 10-week intervention during standard care visits to the outpatient liver cancer clinic at the treating hospital. Acceptability of the intervention will be assessed using a mixed-methods approach via bi-weekly online surveys and an exit telephone interview (see Figure 1). Additional measures that will be taken, but are not considered study outcomes, include body mass, height, resting blood pressure and resting heart rate.

Feasibility

Feasibility outcomes include recruitment rate, retention rate, intervention adherence, intervention fidelity, and safety. The definition and criteria for success for each feasibility outcome are presented in Table 1. Reasons for declining to participate in the study, and reasons for withdrawing from the study after providing consent, will also be recorded in a Consolidated Standards of Reporting Trials (CONSORT) flowchart.

Table 1. Feasibility outcomes for this study

Outcome

Definition

Recruitment rate

The proportion of eligible patients who are approached and give informed consent to participate.

Retention ratea

The proportion of patients who consent to take part in the study and complete the FACT-Hep questionnaire at both baseline and 10-week follow-up.

Intervention adherenceb

i) The mean proportion of exercise sessions attended by patients (verified by intervention facilitator)

ii) The mean proportion of exercise sessions completed at or above a moderate-intensity, assessed subjectively by RPE (rating of ≥3 on the 10-point scale) and objectively via accelerometery (≥1952 counts/min).

Intervention fidelity

Assessed by a research team member attending a 10% sample of the virtual exercise sessions using a standardised checklist to check whether the sessions are delivered in accordance with the protocol.

Safety

The number and type (i.e. serious or non-serious) of adverse events that are related or possibly related to the intervention or study procedures.

aThe Functional Assessment of Cancer Therapy – Hepatobiliary (FACT-Hep) questionnaire was chosen for the assessment of retention rate because this is likely to be our primary outcome for a subsequent randomised controlled trial.

aAdherence to the intervention will be evaluated only in patients who complete the study, defined as patients who complete the FACT-Hep questionnaire at both baseline and 10-week follow-up

Physical function

Physical function will be assessed with the Short Physical Performance Battery (SPPB) and the Liver Frailty Index (LFI). The SPPB is a composite measure of balance, chair stands, and gait speed [32]. Each test is assigned a categorical score from 0 (worst performance) to 4 (best performance) according to standardised criteria, and a total score from 0 to 12 is obtained by summing the scores from the three tests. Higher scores in the SPPB reflect better physical function.

The LFI is a composite measure of hand grip strength, chair stands, and balance [33], and is calculated according to the following formula:

LFI = (–0.330 × sex-adjusted grip strength) + (–2.529 × number of chair stands per second) + (–0.040 × total balance time) + 6

Grip strength is converted into sex-specific z-scores before being entered into the formula [33]. Total balance time is the sum of the three balance tests in seconds (maximum of 30 seconds; see below). Lower scores in the LFI reflect better physical function.

Hand grip strength. Patients will squeeze a hand-held, analogue, grip dynamometer as hard as possible for 2-3 seconds using their dominant hand. Patients will remain stood in an upright bipedal position with their arm fully extended throughout the test. The dynamometer will be individually adjusted according to the size of the patient’s hand. The mean score from three trials will be recorded in kg.

5-repetition sit-to-stand. Patients will begin seated in a firm, armless chair with both arms crossed against their chest. We will ask patients to position themselves on the edge of the chair seat to minimise trunk flexion [34], and instruct them to rise to a full standing position (legs straight) and then return to the seat (full weight on chair) five times, as quickly as they can whilst maintaining correct technique. A practice trial of one repetition will be given to check correct form, followed on by one test trial. The time it takes to complete five sit-to-stands will be recorded in seconds.

Balance. The balance test will involve patients standing unassisted with their feet placed side-by-side, semi-tandem, and semi-tandem for a maximum of 10 seconds each. Recording will stop after 10 seconds or when the patient loses balance (i.e. steps out of position or grabs the researcher’s arm). One trial will be performed in each stance position, with the time recorded in seconds.

4-meter gait speed. Patients will walk at their usual pace for a distance of 4 meters. One practice trial will be given, followed by one test trial with the time recorded in seconds. Walking aids will be allowed if necessary.

Mid-upper arm circumference

The anthropometric measurement of mid-upper arm circumference is a valid measure of muscle mass in non-obese patients [35]. The measurement will be taken with a non-stretching measurement tape at the midpoint between the tip of the acromion and olecranon process of the dominant arm (to the nearest 0.1 cm). Patients will be in a sitting position with the dominant arm hanging relaxed during the measurements [35].

Physical activity

Physical activity will be objectively measured using an ActiGraph GT9X accelerometer worn on the non-dominant wrist for at least 8 hours per day over seven days in the first and last weeks of the intervention. Patients will be asked to wear the accelerometer for the duration of the 10-week intervention, which will also allow us to explore potential diurnal trends in physical activity and monitor exercise intensity during the scheduled exercise sessions. Daily total activity counts, steps, time spent sedentary, and time spent in light, moderate, and vigorous activity will be recorded. Freedson thresholds based on metabolic equivalents will be used to demarcate to intensity of physical activity: sedentary (≤100 counts/min), light (101-1951 counts/min), moderate (1952-5724 counts/min), and vigorous activity (≥5725 counts/min) [36, 37].

Patient-reported outcome measures

It is anticipated that all study questionnaires will be completed in-person at the outpatient liver cancer clinic. However, we will permit questionnaires to be completed remotely if necessary due to time constrains or covid-related restrictions. The Functional Assessment of Cancer Therapy – Hepatobiliary (FACT-Hep) total score will be used to measure disease-specific quality of life [38]. Fatigue will be measured with the Functional Assessment of Chronic Illness Therapy – Fatigue (FACIT-F) total score [39]. We will use the Activities-Specific Balance Confidence Scale (ABC Scale) total score to assess fear of falls [40]. Anxiety and depression symptoms will be assessed via the Hospital Anxiety and Depression Scale (HADS) total subscale scores for anxiety and depression [41]. Self-reported physical activity will be assessed with the Godin Leisure-Time Exercise Questionnaire using the total leisure activity score [42].

Acceptability

We will distribute brief online surveys to patients within one-hour of their second exercise session in weeks 2, 4, 6, 8, and 10 via Google forms. A link to the survey will be distributed via the chat function in Zoom or via email, and patients will be asked to complete the survey as soon as possible. The survey involves nine Likert-like items on a 5-point scale ranging from 0 (“Strongly disagree”) to 5 (“Strongly agree”), as well as an open-ended section that allows patients to freely express their views. Survey items build on previous research [20] and relate to satisfaction with the technology and exercise sessions. The survey questions are available in the supplementary information files. The research team will meet every two weeks and decide whether the exercise protocol requires minor modification based on survey findings and feedback during the sessions.

Acceptability will also be assessed qualitatively with in-depth, semi-structured, one-to-one exit interviews with patients. A member of the research team experienced with telephone interviews, but not involved in intervention delivery, will contact all patients 1-4 weeks after completion of the final follow-up assessment. The interviews will be conducted remotely via telephone or online videoconferencing (Zoom), depending on patient preference. The researcher will facilitate the interviews using a conversational-style approach whilst referring to a topic guide, which is informed by the capability-motivation-opportunity-behaviour (COM-B) model of behaviour [43] and by previous studies exploring experiences and perceptions of exercise [44, 45]. Topics will focus on patients’ perceived expectations, benefits, motives and barriers to the intervention (see supplementary information for topic guide). The topic guide will be used flexibly to allow patients to raise additional issues which they consider important to the study. It is anticipated that each interview will last approximately 30-60 minutes.

Final assessments of acceptability will involve examining reasons for declining to participate amongst eligible patients, reasons for non-adherence to the exercise intervention, and reasons for dropout amongst discontinuing patients.

Safety reporting

Reporting of adverse events will be conducted in line with NuTH’s policy on adverse event reporting for non-clinical trials of investigational medicinal products (CTIMPs). A member of the research team (HR) will be responsible for determining the attribution and seriousness of adverse events and ensuring they are appropriately documented. All adverse events will be recorded in the Trial Master File. We will report serious adverse events that are deemed to be related to study participation to the trial sponsor and the relevant Research Ethics Committee. Serious adverse events are defined as any untoward medical occurrence that: results in death; is life threatening; requires unplanned or prolonged hospitalisation; results in persistent or significant disability or incapacity; or results in a congenital abnormality/birth defect. Non-serious adverse events are defined as any untoward medical occurrence that do not fulfil any of the serious adverse event criteria [46]. Information on adverse events will be collected after written consent has been contained up until the 10-week follow-up. Patients enrolled into the study are covered by indemnity for negligent harm through NHS schemes. Newcastle University has insurance to cover for non-negligent harm arising from the design of the research.

Sample size

There are no clear guidelines on sample size requirements for non-randomised feasibility trials. Thus, our sample size is based on the minimum number of patients required to achieve the key aims of this feasibility study and the number that is achievable to recruit within a 6-month period [47]. Based on recruitment to ongoing studies at NuTH with similar participant eligibility criteria (e.g. ISRCTN16680540), we expect that at least three eligible patients per week will be identified. Assuming that 30% of eligible patients provide consent (which is a conservative estimate based on the mean recruitment rate in similar studies [48]), we will recruit at least 20 patients in a 6-month recruitment period. We consider this number of patients sufficient to provide sufficient information on feasibility and acceptability.

Criteria for success

Based on a systematic review of recruitment, retention, and exercise adherences rates in patients with advanced cancer [48], this feasibility trial will be deemed successful if the following criteria are met:

  • ≥40% of eligible patients provide written consent to take part in the feasibility trial.

  • ≥70% of patients attend at least 14 out of 20 exercise sessions.

  • ≥75% of patients complete the FACT-Hep questionnaire at baseline and 10-week follow-up.

  • No serious adverse events are attributable to the intervention or study procedures.

Data and statistical analysis

Quantitative analysis

The flow of patients throughout the trial will be reported in a CONSORT flowchart. Descriptive statistics will be used to present baseline characteristics, feasibility outcomes and acceptability survey responses. Continuous variables will be described with the mean and standard deviation (SD) and categorical variables will be reported as frequency and proportion. Continuous data with an asymmetrical distribution will be summarised with the median and interquartile range. A paired t-test or Wilcoxon signed-rank test (depending on data distribution) will be used to evaluate changes in outcomes from baseline to post-intervention, with the mean difference and 95% confidence interval from the model presented. Data will be analysed per protocol (i.e. missing data at follow-up will not be imputed).

Qualitative analysis

Exit interviews will be audio-recorded and transcribed verbatim. Anonymised transcripts will be imported into NVivo qualitative data analysis software (version 12) and analysed using reflexive thematic analysis [49, 50]. This analytic method involves the researcher undertaking six iterative phases of: familiarising themselves with the data; generating codes (where we will use an inductive approach); constructing themes; reviewing themes; defining and naming themes; and finally producing the report. All transcripts will be coded independently by one member of the research team, with a proportion (~50%) independently coded by a second team member. Throughout the process, the two researchers will work collaboratively to discuss and refine codes, as well as collating them to develop the potential themes and later reviewing to agree final themes and sub-themes.

Research ethics approval

An independent NHS Research Ethics Committee (North East – Newcastle and North Tyneside 2) has ethically approved the study (IRAS ID: 300809).

Patient and public involvement

We have involved patients and other key stakeholders at various points during the intervention development process. We initially shared an outline of our proposal with the national patient support group; LiverNorth. Their members felt that patients with liver cancer would embrace the opportunity to take part in online exercise sessions with other like-minded individuals, particularly because of the COVID-19 pandemic, which has made many people feel even more isolated. They also felt that the exercise sessions may give patients a sense of control over their prognosis. Subsequently, we convened a multidisciplinary steering group that included patient representatives, healthcare professionals (e.g. physiotherapist and hepatologist), and clinical exercise physiologist. The steering group regularly met online to co-design the intervention based on the best available evidence, logistical concerns, safety, and ways to support intervention adherence. We also had in-depth telephone discussions with five patients currently living with HCC (two receiving supportive care and three receiving active treatment). They expressed their views on various aspects of the intervention, and wherever possible, their preferences were incorporated into the research design. Following the co-design process, we held an online focus group with people living with and beyond cancer to gather their feedback on the prototype intervention, which led to minor modifications to the protocol. Patients will continue to be involved in the study via bi-weekly participant surveys as well as through a Patient Reference Group (PRG). The PRG will provide guidance on key issues such as recruitment and dissemination, and feed directly into the steering group via the group chair.

Modification of the protocol

Any modifications to the protocol will be agreed by the research team and trial sponsor, and approved by an independent NHS Research Ethics Committee.

Discussion

Patients with HCC typically face limited treatment options due to age-related morbidities and the advanced stage at which the disease is diagnosed. Most patients are not eligible for curative treatment and are offered palliative treatment or supportive care only [7]. As a consequence, maintaining QoL and day-to-day function through symptom management is critically important [10]. Strong evidence supports the efficacy of specific doses of supervised exercise training for addressing certain cancer-related symptoms, such as QoL, physical function, fatigue, and symptoms of anxiety and depression [11]. However, there are many barriers to implementing supervised exercise programmes within cancer care pathways, including economic pressures on healthcare systems and personal barriers for patients.

Telehealth exercise offers patients the opportunity to take part in virtually supervised group exercise in their own home [19]. This may remove some of the barriers for exercise participation and offers a relatively low-cost means of delivering exercise at scale for a patient population that covers a wide geographical location. Despite its potential, there are uncertainties relating to the feasibility, acceptability and safety of Telehealth exercise in people living with HCC.

This mixed-methods study will address uncertainties relating to the feasibility and acceptability of delivering live, online, home-based exercise to patients with HCC. The findings will inform whether any modifications are required to refine and optimise the intervention, and the assessment of outcomes will provide information on the likely size and variability of intervention effects. Collectively, the data generated will inform the design of a subsequent, adequately-powered, randomised controlled trial to evaluate the efficacy of the Telehealth exercise intervention.

Declarations

Funding:

This work is supported by an NIHR Newcastle Biomedical Research Centre project grant. The funding source had no role in the design of this study and will not have any role during its execution, analyses, interpretation of the data, or decision to submit results. KH is supported by a NIHR Development and Skills Enhancement Award (NIHR300760). HLR and the conception of this work was supported by CR UK programme grant C18342/A23390 and CR UK HUNTER Accelerator C9380/A26813.

Authors’ contributions:

STO, KH, and HLC conceived the study and are grant holders. STO and KH developed the study design and intervention, and were responsible for writing the first draft of the study protocol. HLC provided clinical oversight and expertise. MCB provided qualitative research expertise and is leading the qualitative analysis of patient interviews. All authors contributed to refinement of the study protocol and approved the final manuscript.

References

  1. Sung H, Ferlay J, Siegel RL, et al. Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin. 2021. https://doi.org/10.3322/caac.21660.
  2. Lin L, Yan L, Liu Y, et al. The Burden and Trends of Primary Liver Cancer Caused by Specific Etiologies from 1990 to 2017 at the Global, Regional, National, Age, and Sex Level Results from the Global Burden of Disease Study 2017. Liver Cancer. 2020;9:563–82. https://doi.org/10.1159/000508568.
  3. Cancer Research UK Liver cancer mortality statistics. https://www.cancerresearchuk.org/health-professional/cancer-statistics/statistics-by-cancer-type/liver-cancer/mortality. Accessed 23 Aug 2021.
  4. Lanza E, Masetti C, Messana G, et al. Sarcopenia as a predictor of survival in patients undergoing bland transarterial embolization for unresectable hepatocellular carcinoma. PLoS One. 2020;15:e0232371. https://doi.org/10.1371/journal.pone.0232371.
  5. Hirota K, Kawaguchi T, Koya S, et al. Clinical utility of the Liver Frailty Index for predicting muscle atrophy in chronic liver disease patients with hepatocellular carcinoma. Hepatol Res. 2020;50:330–41. https://doi.org/10.1111/hepr.13453.
  6. Cancer Research UK Liver cancer survival statistics. https://www.cancerresearchuk.org/health-professional/cancer-statistics/statistics-by-cancer-type/liver-cancer/survival. Accessed 23 Aug 2021.
  7. Rich NE, Yopp AC, Singal AG. Medical Management of Hepatocellular Carcinoma. J Oncol Pract. 2017;13:356–64. https://doi.org/10.1200/JOP.2017.022996.
  8. Shun S-C, Chen C-H, Sheu J-C, et al. Quality of Life and Its Associated Factors in Patients with Hepatocellular Carcinoma Receiving One Course of Transarterial Chemoembolization Treatment: A Longitudinal Study. Oncologist. 2012;17:732–9. https://doi.org/10.1634/theoncologist.2011-0368.
  9. Miaskowski C, Dodd M, Lee K. (2004) Symptom clusters: the new frontier in symptom management research. J Natl Cancer Inst Monogr 17–21. https://doi.org/10.1093/jncimonographs/lgh023.
  10. European Association for the Study of the Liver. EASL Clinical Practice Guidelines: Management of hepatocellular carcinoma. J Hepatol. 2018;69:182–236. https://doi.org/10.1016/j.jhep.2018.03.019.
  11. Campbell KL, Winters-Stone KM, Wiskemann J, et al. Exercise Guidelines for Cancer Survivors: Consensus Statement from International Multidisciplinary Roundtable. Med Sci Sports Exerc. 2019;51:2375–90. https://doi.org/10.1249/MSS.0000000000002116.
  12. Elshahat S, Treanor C, Donnelly M. Factors influencing physical activity participation among people living with or beyond cancer: a systematic scoping review. Int J Behav Nutr Phys Act. 2021;18:50. https://doi.org/10.1186/s12966-021-01116-9.
  13. IJsbrandy C, Hermens RPMG, Boerboom LWM, et al. Implementing physical activity programs for patients with cancer in current practice: patients’ experienced barriers and facilitators. J Cancer Surviv. 2019;13:703–12. https://doi.org/10.1007/s11764-019-00789-3.
  14. McGowan EL, Speed-Andrews AE, Blanchard CM, et al. Physical activity preferences among a population-based sample of colorectal cancer survivors. Oncol Nurs Forum. 2013;40:44–52. https://doi.org/10.1188/13.ONF.44-52.
  15. Rogers LQ, Markwell SJ, Verhulst S, et al. Rural breast cancer survivors: exercise preferences and their determinants. Psychooncology. 2009;18:412–21. https://doi.org/10.1002/pon.1497.
  16. Hardcastle SJ, Cohen PA. Effective Physical Activity Promotion to Survivors of Cancer Is Likely to Be Home Based and to Require Oncologist Participation. J Clin Oncol. 2017;35:3635–7. https://doi.org/10.1200/JCO.2017.74.6032.
  17. Stevinson C, Capstick V, Schepansky A, et al. Physical activity preferences of ovarian cancer survivors. Psychooncology. 2009;18:422–8. https://doi.org/10.1002/pon.1396.
  18. Orange ST, Gilbert SE, Brown MC, Saxton JM. Recall, perceptions and determinants of receiving physical activity advice amongst cancer survivors: a mixed-methods survey. Support Care Cancer. 2021;29:6369–78. https://doi.org/10.1007/s00520-021-06221-w.
  19. Bland KA, Bigaran A, Campbell KL, et al. Exercising in Isolation? The Role of Telehealth in Exercise Oncology During the COVID-19 Pandemic and Beyond. Phys Ther. 2020. https://doi.org/10.1093/ptj/pzaa141.
  20. Schwartz H, Har-Nir I, Wenhoda T, Halperin I. Staying physically active during the COVID-19 quarantine: exploring the feasibility of live, online, group training sessions among older adults. Transl Behav Med. 2021;11:314–22. https://doi.org/10.1093/tbm/ibaa141.
  21. Li F, Harmer P, Voit J, Chou L-S. Implementing an Online Virtual Falls Prevention Intervention During a Public Health Pandemic for Older Adults with Mild Cognitive Impairment: A Feasibility Trial. Clin Interv Aging. 2021;16:973–83. https://doi.org/10.2147/CIA.S306431.
  22. Morrison KS, Paterson C, Toohey K. The Feasibility of Exercise Interventions Delivered via Telehealth for People Affected by Cancer: A Rapid Review of the Literature. Semin Oncol Nurs. 2020;36:151092. https://doi.org/10.1016/j.soncn.2020.151092.
  23. Craig P, Dieppe P, Macintyre S, et al (2008) Developing and evaluating complex interventions: the new Medical Research Council guidance. BMJ 337:. https://doi.org/10.1136/bmj.a1655.
  24. Chan A-W, Tetzlaff JM, Gøtzsche PC, et al. SPIRIT 2013 explanation and elaboration: guidance for protocols of clinical trials. BMJ. 2013;346:e7586. https://doi.org/10.1136/bmj.e7586.
  25. Borg G. Borg’s Perceived Exertion and Pain Scales. Champaign: Human Kinetics; 1998.
  26. Thompson PD, Franklin BA, Balady GJ, et al. Exercise and acute cardiovascular events placing the risks into perspective: a scientific statement from the American Heart Association Council on Nutrition, Physical Activity, and Metabolism and the Council on Clinical Cardiology. Circulation. 2007;115:2358–68. https://doi.org/10.1161/CIRCULATIONAHA.107.181485.
  27. Buatois S, Perret-Guillaume C, Gueguen R, et al. A simple clinical scale to stratify risk of recurrent falls in community-dwelling adults aged 65 years and older. Phys Ther. 2010;90:550–60. https://doi.org/10.2522/ptj.20090158.
  28. Myers AM, Fletcher PC, Myers AH, Sherk W. Discriminative and evaluative properties of the activities-specific balance confidence (ABC) scale. J Gerontol A Biol Sci Med Sci. 1998;53:M287–94. https://doi.org/10.1093/gerona/53a.4.m287.
  29. Li F, Harmer P, Fitzgerald K, et al. Effectiveness of a Therapeutic Tai Ji Quan Intervention vs a Multimodal Exercise Intervention to Prevent Falls Among Older Adults at High Risk of Falling: A Randomized Clinical Trial. JAMA Intern Med. 2018;178:1301–10. https://doi.org/10.1001/jamainternmed.2018.3915.
  30. Garber CE, Blissmer B, Deschenes MR, et al. American College of Sports Medicine position stand. Quantity and quality of exercise for developing and maintaining cardiorespiratory, musculoskeletal, and neuromotor fitness in apparently healthy adults: guidance for prescribing exercise. Med Sci Sports Exerc. 2011;43:1334–59. https://doi.org/10.1249/MSS.0b013e318213fefb.
  31. American College of Sports Medicine. ACSM’s Guidelines for Exercise Testing and Prescription. 11th ed. Alphen aan den Rijn: Wolters Kluwer; 2020.
  32. Phu S, Kirk B, Bani Hassan E, et al. The diagnostic value of the Short Physical Performance Battery for sarcopenia. BMC Geriatr. 2020;20:242. https://doi.org/10.1186/s12877-020-01642-4.
  33. Lai JC, Covinsky KE, Dodge JL, et al. Development of a Novel Frailty Index to Predict Mortality in Patients with End-Stage Liver Disease. Hepatology. 2017;66:564–74. https://doi.org/10.1002/hep.29219.
  34. Orange ST, Metcalfe JW, Liefeith A, Jordan AR. Validity of various portable devices to measure sit-to-stand velocity and power in older adults. Gait Posture. 2020;76:409–14. https://doi.org/10.1016/j.gaitpost.2019.12.003.
  35. Saito R, Ohkawa S, Ichinose S, et al. Validity of mid-arm muscular area measured by anthropometry in nonobese patients with increased muscle atrophy and variation of subcutaneous fat thickness. Eur J Clin Nutr. 2010;64:899–904. https://doi.org/10.1038/ejcn.2010.87.
  36. Leinonen A-M, Ahola R, Kulmala J, et al. Measuring Physical Activity in Free-Living Conditions—Comparison of Three Accelerometry-Based Methods. Front Physiol. 2017;7:681. https://doi.org/10.3389/fphys.2016.00681.
  37. Freedson PS, Melanson E, Sirard J. Calibration of the Computer Science and Applications, Inc. accelerometer. Med Sci Sports Exerc. 1998;30:777–81. https://doi.org/10.1097/00005768-199805000-00021.
  38. Heffernan N, Cella D, Webster K, et al. Measuring health-related quality of life in patients with hepatobiliary cancers: the functional assessment of cancer therapy-hepatobiliary questionnaire. J Clin Oncol. 2002;20:2229–39. https://doi.org/10.1200/JCO.2002.07.093.
  39. Webster K, Cella D, Yost K. The Functional Assessment of Chronic Illness Therapy (FACIT) Measurement System: properties, applications, and interpretation. Health Qual Life Outcomes. 2003;1:79. https://doi.org/10.1186/1477-7525-1-79.
  40. Powell LE, Myers AM. (1995) The Activities-specific Balance Confidence (ABC) Scale. J Gerontol A Biol Sci Med Sci 50A:M28-34. https://doi.org/10.1093/gerona/50a.1.m28.
  41. Bjelland I, Dahl AA, Haug TT, Neckelmann D. The validity of the Hospital Anxiety and Depression Scale. An updated literature review. J Psychosom Res. 2002;52:69–77. https://doi.org/10.1016/s0022-3999(01)00296-3.
  42. Amireault S, Godin G, Lacombe J, Sabiston CM. The use of the Godin-Shephard Leisure-Time Physical Activity Questionnaire in oncology research: a systematic review. BMC Med Res Methodol. 2015;15:60. https://doi.org/10.1186/s12874-015-0045-7.
  43. Michie S, van Stralen MM, West R. The behaviour change wheel: a new method for characterising and designing behaviour change interventions. Implement Sci. 2011;6:42. https://doi.org/10.1186/1748-5908-6-42.
  44. Fisken A, Keogh JWL, Waters DL, Hing WA. Perceived benefits, motives, and barriers to aqua-based exercise among older adults with and without osteoarthritis. J Appl Gerontol. 2015;34:377–96. https://doi.org/10.1177/0733464812463431.
  45. Henwood T, Tuckett A, Edelstein O, Bartlett H. Exercise in later life: the older adults’ perspective about resistance training. Ageing Soc. 2011;31:1330–49.
  46. European Medicines Agency. (1994) Clinical safety data management: definitions and standards for expedited reporting.
  47. Lakens D. (2021) Sample Size Justification. PsyArXiv. https://doi.org/10.31234/osf.io/9d3yf.
  48. Sheill G, Guinan E, Brady L, et al. Exercise interventions for patients with advanced cancer: A systematic review of recruitment, attrition, and exercise adherence rates. Palliat Support Care. 2019;17:686–96. https://doi.org/10.1017/S1478951519000312.
  49. Braun V, Clarke V. Using thematic analysis in psychology. Qualitative Research in Psychology. 2006;3:77–101. https://doi.org/10.1191/1478088706qp063oa.
  50. Clarke V, Braun V, Terry G, Hayfield N. Thematic analysis. In: Liamputtong P, editor. Handbook of research methods in health and social sciences. Singapore: Springer; 2019. pp. 843–60.