Background
Cardiopulmonary exercise testing (CPET) provides an objective, non-invasive measure of functional capacity (ATS/ARCP,
2003). CPET is an exercise stress test with concomitant expired gas analysis. Expired tidal volumes, oxygen and carbon dioxide concentrations, heart rate and respiratory rate are measured and a number of metabolic, ventilatory, gas exchange and cardiovascular variables are derived (ATS/ARCP,
2003). Since Older et al.(
1999) first demonstrated that a lower anaerobic threshold was associated with increased mortality in elderly patients undergoing intra-abdominal surgery, more than 30 published case cohort studies have reported that CPET predicts postoperative morbidity and mortality (Wilson et al.
2010; Snowden et al.
2010; Carlisle and Swart
2007; Moran et al.
2016). Consequently, CPET is increasingly forming part of the preoperative assessment. It provides an individualised risk assessment that is used to apprise the decision to proceed to surgery, to inform collaborative decision-making and patient consent, to triage patients to the appropriate level of care perioperatively (e.g. critical care vs surgical ward care), to guide intraoperative anaesthetic techniques, to optimise medical comorbidities preoperatively, to diagnose unexpected comorbidity and increasingly to direct individualised preoperative exercise programmes (prehabilitation) (Older and Levett
2017; Levett and Grocott
2015).
Two previous surveys in England have reported that the use of CPET preoperatively is increasing with the number of trusts offering a service rising from 30 in 2009 to 53 in 2011 (Huddart et al.
2013; Simpson and Grocott
2009). With the implementation of a new diagnostic or prognostic test, it is important to establish whether consistent standards of practice are employed. Valid and reproducible results are vital if the test is used to inform the decision to proceed to surgery, the consent process, preoperative optimisation and the location of perioperative care (e.g. critical care vs ward care). We aimed to evaluate how CPET services have evolved across the UK, to identify who is performing the tests, which patients are being tested, how the tests are performed and interpreted and the funding of CPET services within the NHS.
Methods
Contact details for all NHS trusts in the UK were obtained from the NHS website (NHS Authorities and Trusts,
n.d.). We contacted trusts to establish whether they performed adult elective surgery and identified 197 such trusts. The anaesthetic department was contacted by telephone in each trust and asked if they had a CPET service and to provide details of their CPET and pre-assessment leads. Trusts were telephoned repeatedly until a full list of contact details was obtained.
A structured questionnaire was subsequently sent to the identified service leads. This structured questionnaire was designed using an online survey tool, comprising 211 questions with 4 response arms: trusts with CPET, trusts without CPET, trusts setting up CPET and trusts who had tried but failed to set up CPET (Survey Monkey,
n.d.). It contained primarily multiple-choice questions with free text where appropriate. It was not compulsory to answer all question stems of the survey, and some questions permitted respondents to select more than one response.
Questions were written to establish the following:
1.
How many centres are performing CPET
2.
The types of patients being tested
3.
The protocols and equipment being used
4.
The methods used for physiological interpretation of the anaerobic threshold
5.
Who is performing and reporting the tests
6.
The information given in the CPET report
The online survey was sent to each contact email address in November 2016 with reminders sent to non-responders until March 2017. Data was collected by the online tool and extracted directly for analysis using Microsoft Excel 2011 Version 14.7.0 (Microsoft Corporation, Redmond, WA USA).
Discussion
We have found that in excess of 30, 000 preoperative CPET tests are being performed annually in the UK and that the number of preoperative CPET services has doubled since 2011 (from 53 to 106). The scope of CPET practice has evolved and expanded since 2011 with more testing in patients undergoing thoracic, urology, hepatobiliary and gynaecology surgery. Furthermore, CPET results are increasingly used to direct preoperative exercise programmes. This may reflect the evolving evidence base supporting its predictive role and the role of prehabilitation (Older and Levett
2017). We have also established that preoperative CPET services are increasingly involved in diagnostic CPET for other specialities.
Hospitals without a CPET service and hospitals who had tried to set up service but failed cited lack of funding as the most common reason. This was also the most frequent response in
Huddart’s 2011 survey, reflecting continued financial constraints in the NHS (Huddart et al.
2013). There has however been progress in the funding since 2011 with more than 40% now receiving fees from clinical commissioning groups. Furthermore, the majority of clinical sessions are now funded as clinical activity in clinicians’ job plans.
The vast majority of preoperative CPET is performed and interpreted by anaesthetists, with support from a variety of allied health professionals and other physicians. Patients are primarily being selected for testing on the basis of the proposed surgical procedure, but perceived risk and comorbidities are also taken into account. Reporting in the majority of cases involves both physiological variables and advice about the perioperative management and risk stratification of patients. There is increasing focus on preoptimisation by medical referral or exercise interventions compared with previous surveys (Huddart et al.
2013; Simpson and Grocott
2009). This may reflect the growing evidence base supporting prehabilitation prior to surgery (West et al.
2015; Barakat et al.
2016; Barberan-Garcia et al.
2017).
We have identified considerable variability in the conduct of CPET with regards to consent and medical supervision. Given the rare but potentially significant adverse events associated with CPET (e.g. arrhythmias or exercise-induced ischaemia), it would seem appropriate that a formal consent process is followed and medical supervision standardised when the test is performed by a non-medical personnel. This is the case in other areas of clinical CPET practice (Myers et al.
2014).
The anaerobic threshold (AT) is cited as one of the most important variables for advising on risk given its predictive utility in the CPET literature (Moran et al.
2016). The AT can be used to identify a patient population at high risk of postoperative morbidity and mortality. The threshold value used to delineate this high risk patient population varies with the surgical procedure and has been summarised in recent reviews (Moran et al.
2016; Older and Levett
2017). There is known inter-observer variability in determination of the anaerobic threshold (Sinclair et al.
2009; Myers et al.
2010). Three-point determination of the AT, using the V-slope or modified V-slope method with confirmation from the ventilatory response to exercise, is the most reliable and valid approach for AT determination (Ward
2007). Although the majority of CPET services used this approach, this was not consistent. Of concern, in 8% of services, the automated AT generated by the software was used to determine the AT. The exact methods used for automated AT detection in commercial CPET systems vary, but are based on linear regression of the VO
2-VCO
2 relationship—the V-slope method. Automated ATs should be interpreted with caution. The manufacturers recommend that they are used to support clinician identification of the AT and that they should not be used in isolation. The kinetic phase at the start of the ramp, and data above the respiratory compensation point must be excluded from the regression analysis, which requires manual interrogation of the data. Furthermore, in the presence of a curvilinear
\( \dot{V}{CO}_2 \)-
\( \dot{V}{O}_2 \) relationship or very noisy respiratory data (for example in the presence of significant lung disease), linear regression may not accurately identify the AT. If data is to be compared between centres, standardised interpretation is important. There is an appreciation of the importance of standardisation in the preoperative community as 96.5% of those surveyed supported the introduction of standardised training for CPET practitioners.
A variety of other variables is also being used to evaluate perioperative risk and to contribute to informed consent and shared decision-making. These include the peak VO
2 and VE/VCO
2 reflecting the CPET evidence base (Older and Levett
2017). In some services, physiological variables are reported alone; in others, the CPET data is used in combination with life expectancy data and other perioperative scores (POSSUM (Copeland et al.
1991), Lee Revised Cardiac Risk Index (RCRI) (Lee et al.
1999), National Surgical Quality Improvement Programme (NSQIP) (Khuri et al.
1998), Surgical Outcome Risk Tool (SORT) (Protopapa et al.
2014; Wong et al.
2017)), to provide a more comprehensive risk evaluation and inform perioperative care. The approach used is not consistent across centres. This may reflect the different organisational structure of CPET services within the perioperative period. In some centres, CPET forms part of a high-risk pre-assessment or shared decision-making clinic, run by anaesthetists, and the report incorporates a comprehensive risk analysis and plan for the perioperative period reflecting an integrated approach to comprehensive perioperative care. In other centres, CPET functions more like an external referral to a separate team with a report of the physiological variables produced by the CPET team which is subsequently used by the perioperative team at pre-assessment to contribute to the comprehensive risk assessment. If the latter approach is taken, it is important that the perioperative team are expert in the risk implications of the physiological data in the CPET report and the relevant risk thresholds. Equally in order to contribute to preoperative decision-making, it is important that the test is performed sufficiently early in the patient pathway to permit preoperative optimisation (Grocott et al.
2017).
In order to ensure consistent data quality, it is essential that CPET equipment is regularly maintained and serviced. In addition, validation of reporting by internal and external review is important to ensure reporting quality. Only half of the centres surveyed performed internal validation with other clinicians within the service reviewing results, and 3% performed external validation. The low rate of external validation is probably affected by the absence of a national network of perioperative CPET centres to support the exchange of data between groups and external review. Of note, 87.2% of centres suggested they would support establishing a national network of perioperative CPET centres on the national society for perioperative exercise testing and training website (POETTS,
http://www.poetts.co.uk) to facilitate peer support and mentoring. As a consequence, a peer network has been established by POETTS and will imminently be available on the website. Recommendations for internal and external validation have been made in recently published perioperative CPET clinical guidelines (Levett et al.
2018).
The evidence base supporting perioperative CPET is currently largely retrospective and single centre (Older and Levett
2017) although multicentre analyses have recently been published (Carlisle et al.
2015; West et al.
2016). Recent systematic reviews have made recommendations about risk thresholds for major surgical patients that are based on results from surgical cohorts from the 1980s to the present day and may not reflect current practice (e.g. data predates the advent of laparoscopic surgery) (Moran et al.
2016). The validity of these historical thresholds for current practice is questionable. There is an urgent requirement to identify contemporaneous risk thresholds. Our survey has revealed the very high volume of tests being performed annually in the UK. There is consequently the opportunity to collect CPET and outcome data nationally to inform risk thresholds based on recent, local data. The aim of any such initiative should be to provide procedure-specific, contemporaneous risk thresholds and information to inform perioperative practice. The database should contain CPET variables, procedure details, complications, length of hospital and critical care stay and mortality. It should link with other perioperative quality improvement datasets that are being collected such as PQIP (perioperative quality improvement programme at the Health Services Research Centre, Royal College of Anaesthetists) (Perioperative Quality Improvement Programme at the Health Services Research Centre, Royal College of Anaesthetists,
n.d.). 95.3% of those who responded to the survey stated they would consider contributing to a national CPET database suggesting there is a desire for such a project within the CPET community.
The survey has some weaknesses. Responses to the online survey were incomplete in some cases as we did not make the answer to all questions mandatory. Its strengths are that it is the first survey to comprehensively cover all acute trusts in the United Kingdom. Furthermore, the scope of the survey was broadly covering the structure, conduct, reporting and funding of CPET nationally. We had a complete response to our telephone survey, and our response rate to the subsequent online survey was higher than the previous two surveys. This may reflect persistence with email and telephone reminders to the participants.