Cost-effectiveness of an insertable cardiac monitor in a high-risk population in the UK

Claudia I Rinciog; Laura M Sawyer; Alexander Diamantopoulos; Mitchell S V Elkind; Matthew Reynolds; Stylianos I Tsintzos; Paul D Ziegler; Maria E Quiroz; Claudia Wolff; Klaus K Witte

doi:10.1136/openhrt-2019-001037

. 2019 Jun 20;6(1):e001037. doi: 10.1136/openhrt-2019-001037

Cost-effectiveness of an insertable cardiac monitor in a high-risk population in the UK

Claudia I Rinciog ^1,^✉, Laura M Sawyer ¹, Alexander Diamantopoulos ¹, Mitchell S V Elkind ², Matthew Reynolds ³, Stylianos I Tsintzos ⁴, Paul D Ziegler ⁵, Maria E Quiroz ⁵, Claudia Wolff ⁴, Klaus K Witte ⁶

PMCID: PMC6593196 PMID: 31297227

Abstract

Objective

To evaluate the cost-effectiveness of insertable cardiac monitors (ICMs) compared with standard of care (SoC) for detecting atrial fibrillation (AF) in patients at high risk of stroke (CHADS₂ >2), using a UK National Health Service (NHS) perspective.

Methods

Using patient characteristics and clinical data from the REVEAL AF trial, a Markov model assessed the cost-effectiveness of detecting AF with an ICM compared with SoC. Costs and benefits were extrapolated across modelled patient lifetime. Ischaemic and haemorrhagic strokes, intracranial and extracranial haemorrhages and minor bleeds were modelled. Diagnostic and device costs were included, plus costs of treating stroke and bleeding events and costs of oral anticoagulants (OACs). Costs and health outcomes, measured as quality-adjusted life years (QALYs), were discounted at 3.5% per annum. One-way deterministic and probabilistic sensitivity analyses (PSA) were undertaken.

Results

The total per-patient cost for ICM was £13 360 versus £11 936 for SoC (namely, annual 24 hours Holter monitoring). ICMs generated a total of 6.50 QALYs versus 6.30 for SoC. The incremental cost-effectiveness ratio (ICER) was £7140/QALY gained, below the £20 000/QALY acceptability threshold. ICMs were cost-effective in 77.4% of PSA simulations. The number of ICMs needed to prevent one stroke was 21 and to cause a major bleed was 37. ICERs were sensitive to assumed proportions of patients initiating or discontinuing OAC after AF diagnosis, type of OAC used and how intense the traditional monitoring was assumed to be under SoC.

Conclusions

The use of ICMs to identify AF in a high-risk population is cost-effective for the UK NHS.

Keywords: atrial fibrillation, insertable cardiac monitor, cost-effectiveness analysis, economics, oral anticoagulation therapy

Key questions.

What is already known about this subject?

Atrial fibrillation (AF) is a major risk factor for strokes that can be prevented via oral anticoagulation (OAC). Opportunistic, symptom-based, and single time-point diagnostic tests have limited yields. Continuous monitoring with an insertable cardiac monitor (ICM) in the REVEAL AF study demonstrated a high incidence of AF in high-risk patients where previous external monitoring (≥24 hours) was negative. The cost-effectiveness of ICM monitoring in this population is unknown.

What does this study add?

In a population with mean CHADS₂ score of 2.94, the cost per quality-adjusted life-year gained with ICM compared with Standard of Care (SoC) was £7140, a value well below conventional thresholds for cost-effectiveness. Results were sensitive to the cost of SoC and to rates of uptake and duration of OAC therapy after diagnosis.

How might this impact on clinical practice?

The use of ICMs to detect AF and identify high-risk candidates for OAC improves health outcomes relative to SoC at an acceptable extra cost to the UK National Health Service.

Introduction

Atrial fibrillation (AF) has long been associated with stroke risk.^{1 2} Although anticoagulation therapy can effectively reduce stroke risk in patients with AF, initial diagnosis can be challenging. Symptoms may be non-specific, AF may be intermittent³ and current opportunistic short-term monitoring solutions (such as wearing a Holter monitor for 24 hours) are not well suited to detect all AF episodes. Further, correlation of even specific symptoms and a pathological underlying rhythm can be difficult.⁴

Insertable cardiac monitors (ICMs) can continuously monitor patients for AF. The REVEAL AF study⁵ used Reveal^® (Medtronic, Dublin, Ireland) ICM devices to detect AF. The study patients had non-specific symptoms, sufficient stroke risk factors to require oral anticoagulation (OAC) therapy should AF be detected and no AF found following at least 24 hours of external monitoring performed within 90 days prior to study enrolment. After 18 months, the AF detection rate for episodes lasting at least 6 min was found to be 29.3%; at 30 months, the rate was 39.8%.

ICM use in this patient population is clinically effective in diagnosing previously undetected AF but its cost-effectiveness compared with standard care (SoC) in this application is unknown.

Methods

A Markov model was created to compare costs and benefits of Reveal^® ICM versus SoC in patients with high risk of stroke but no confirmed AF diagnosis. Based on a similar analysis in cryptogenic stroke,⁶ the model estimated monitoring and treatment costs from a UK NHS perspective, and health benefits as quality-adjusted life years (QALYs), discounted at 3.5% annually.⁷ The model allowed estimation of life-years gained and stroke events avoided. The model cohort was set up to have the same baseline characteristics as recorded in the REVEAL AF clinical trial⁵ (Clinicaltrials.gov, NCT01727297) (see online supplementary file 1).

Supplementary data

openhrt-2019-001037supp001.docx^{(550.9KB, docx)}

A lifetime horizon captured all relevant costs and health-related quality of life (QoL) effects. Cycle length for recording outcomes was 3 months, matching follow-up intervals in the REVEAL AF trial.

Model structure

The model estimates both the efficacy and costs of the ICM device itself as well as the potential costs and health effects of timely and accurate diagnosis.

In the model’s hypothetical cohort, all patients with underlying AF are assumed to be undiagnosed at baseline. In each cycle, patients with AF may remain undiagnosed, have existing AF detected, or, for patients with no underlying AF initially, develop AF. Patients in whom AF is detected are assumed to receive new OAC (NOAC) therapy (non-vitamin-K OAC); by contrast, patients with undetected AF will have no change in their treatment. Thus, patients with undetected AF are assumed not to receive anticoagulation for stroke prevention. Patients who have a stroke will subsequently move to a post-stroke health state, where they are assumed to remain. AF detection status and treatment received can still change in these states, but patients cannot transit to other states except death.

Movement of patients through the model is shown in figure 1.

Model flow. *NOACs are administered in base-case analysis and warfarin is substituted in sensitivity analysis. AF, atrial fibrillation; CRNM, clinically relevant non-major; ECH, extracranial haemorrhage; HS, haemorrhagic stroke; ICH, intracranial haemorrhage; IS, ischaemic stroke; NOAC, new oral anticoagulants.

Input parameters

Population

The patient cohort reflects the baseline characteristics of the REVEAL AF trial population, with 72.6% receiving aspirin treatment and 20.3% having a history of stroke events in the year prior to recruitment. The average patient entered the model aged 71.3 and with a virtual CHADS₂ score of 2.94. The distribution of CHADS₂ stroke risk scores also matched the REVEAL AF trial population (see online supplementary file 2).

Probabilities

Event probabilities used in the model are shown in table 1. Values were derived from published studies of baseline risks and calculated via drug treatment effects applied on those risks (see online supplementary file 3).

Table 1.

Annual risks and severity of bleeds and haemorrhagic stroke, by anticoagulant treatment received

	No treatment	Aspirin	NOAC*†	Warfarin*
ICH‡	0.2%	0.5%	0.3%	0.8%
HS§	0.1%	0.3%	0.2%	0.5%
Other ICH	0.1%	0.2%	0.1%	0.3%
ECH¶	2.0%	2.5%	2.7%	3.1%
GI bleed	0.8%	1.0%	1.1%	1.3%
Other ECH	1.2%	1.4%	1.6%	1.8%
All major bleeds	2.2%	2.9%	3.1%	3.8%
CRNM bleed	5.3%	6.9%	7.9%	9.5%
HS severity	Mild: 28%; moderate: 23%; severe: 12% fatal: 37%^{14 15}
Case fatalities	Due to other ICH: 13%, due to ECH: 2%^{14 15}

Open in a new tab

*NOAC was used as treatment in base-case analysis and warfarin was considered in sensitivity analysis.

†A class effect was assumed by taking the average across apixaban, dabigatran (low and high dose), rivaroxaban, edoxaban (low and high dose).¹¹

‡ICHs (59.7%) were assumed to be HS.^{14 15}

§HS risk was adjusted by a factor of 1.97 (95% CI 1.79 to 2.16) per decade.³¹

¶ECHs (41.8%) were assumed to be GI bleeds.^{14 15}

CRNM, clinically relevant non-major;ECH, extracranial haemorrhage;GI, gastrointestinal;HS, haemorrhagic stroke;ICH, extracranial haemorrhage;NOAC, new oral anticoagulant.

AF incidence, detection and subsequent treatment

The model definition of AF corresponded to that used in the REVEAL AF trial.⁵ Base-case AF episodes were defined as lasting for ≥6 min, while a scenario analysis explored the impact of AF episodes lasting for ≥5.5 hours (see online supplementary file 2). AF detection rates for patients receiving an ICM (Reveal^®, Medtronic) were modelled based on the first 30 months of observations from the REVEAL AF trial (figure 2). Beyond month 30, a constant long-term AF risk of 3.9% per cycle was derived based on average detection rates across the REVEAL AF study (excluding the first 3 months). Because ICMs may fail to identify some episodes of AF, the calculation of AF incidence incorporated an assumed device sensitivity of 96.1%.⁸

AF detection rates in REVEAL AF—all patients. AF, atrial fibrillation; ICM, insertable cardiac monitor.

The analysis assumed that on AF detection, all patients were administered NOAC therapy, in accordance with National Institute for Health and Care Excellence (NICE) guidance.⁹ In a scenario analysis, a lower NOAC uptake (66.35%) was assumed, based on an average of NOAC uptake from published sources.^{5 10}

Ischaemic stroke risk and severity

In each cycle, the risk of having an ischaemic stroke (IS) was based on patients’ AF status, virtual CHADS₂ score, anticoagulation treatment and age (see table 2). IS risk calculation involved synthesis from several publications.^{1 11–13} IS severity was assigned to a distribution based on published cost-effectiveness analyses^{14 15}; this distribution was independent of anticoagulation treatment status (see online supplementary file 4). The probabilities for events and severity are summarised in table 2.

Table 2.

Annual stroke risk and severity by CHADS₂ risk score, AF status and anticoagulant treatment received

CHADS₂ score	No AF		AF
CHADS₂ score	No treatment	Aspirin	No treatment	Aspirin	NOAC*†	Warfarin*
0	0.2%	0.2%	1.1%	0.8%	0.3%	0.3%
1	0.6%	0.5%	3.1%	2.2%	0.8%	0.8%
2	1.3%	0.9%	6.3%	4.5%	1.7%	1.7%
3	2.5%	1.8%	12.0%	8.6%	3.3%	3.2%
4	3.2%	2.3%	15.3%	10.9%	4.2%	4.1%
5	3.6%	2.6%	17.2%	12.3%	4.7%	4.6%
6	4.0%	2.9%	19.2%	13.7%	5.3%	5.1%
IS severity	Mild: 42%; moderate: 26%; severe: 10%; fatal: 22%

Open in a new tab

*NOAC was used as treatment in base-case analysis and warfarin was considered in sensitivity analysis.

†A class-effect for NOAC was assumed by taking the average efficacy of apixaban, dabigatran (low and high dose), rivaroxaban, edoxaban (low and high dose).¹¹

‡IS risk was adjusted by a factor of 1.46 (95% CI 0.8 to 2.16) per decade.¹³

AF, atrial fibrillation;IS, ischaemic stroke;NOAC, new oral anticoagulant.

Bleeding events and anticoagulation therapy changes

Bleed risks were assumed to be related to NOAC treatment and age. The type and likelihood of bleeds were based on published analyses,^{14 15} and their severity (see online supplementary file 4) was independent of any anticoagulation treatment given (see table 1).⁶ Non-fatal extracranial bleeds were assumed to cause temporary (6 week) discontinuation of NOACs in 75% of patients receiving NOAC and permanent discontinuation in 25% of patients receiving NOACs. Among patients on aspirin, 25% were precluded from receiving NOAC in future if they experienced a bleed.^{16 17} Non-fatal intracranial bleeds caused temporary (6 week) discontinuation of NOAC therapy in 44% of patients on NOAC, whereas 56% had their NOAC therapy discontinued permanently (or banned from use in future, where the event occurred while the patient was on aspirin).^{16 17} Clinically relevant non-major (CRNM) bleed did not lead to discontinuation of NOAC. Haemorrhagic strokes while on NOAC therapy led to discontinuation and switch to aspirin in 100% of cases—or preclusion from receiving NOAC in future if the patient was on aspirin. NOACs were not restarted in patients with haemorrhagic stroke (HS) even if they later had a positive AF diagnosis. Finally, 16% of patients on NOAC were assumed to discontinue treatment each year for reasons unrelated to bleeding events.¹⁵

In terms of cost and QoL impact, non-fatal extracranial haemorrhage, other intracranial haemorrhage (ie, non-haemorrhagic strokes) and CRNM bleeds had temporary consequences applied to the cycle in which the bleed occurred. By contrast, IS and HS were assumed to have permanent consequences for ongoing costs, QoL and long-term mortality risk, with different levels of impact depending on stroke severity (table 1).

Mortality

Age-dependent background mortality in the model was based on UK life tables adjusted as required to exclude deaths due to cerebrovascular events.¹⁸ Following non-fatal strokes, mortality risk increased depending on stroke severity and treatment (see online supplementary file 5).

Health-related QOL

Baseline EuroQol-five dimension data came from the REVEAL AF study. Utility data for health states and acute events were adapted from a similar analysis in patients with cryptogenic stroke,⁶ adjusting for the absence of stroke history in majority of patients.14 15 19 20 Modelled utilities are presented in table 3 and further detailed in the online supplementary file 6.

Table 3.

Cost and utilities of interventions, events and health states

Event, intervention or health state	Mean cost (£)	SE (£)	Mean utility	SE	Source
Stroke and bleed events*
Mild IS	3783	997	0.730	0.014	Luengo-Fernandez et al (2013a,b) ^{19 20}†
Moderate IS	19 737	2451	0.500	0.037
Severe IS	26 957	3947	0.130	0.057
Fatal IS	3403	551	0.000	–
Mild HS	11 016	2017	0.730	0.014
Moderate HS	28 301	5563	0.500	0.037
Severe HS	47 872	12 911	0.130	0.057
Fatal HS	1771	667	0.000	–
Disutility for all recurrent (secondary) stroke events (acute period)	–		−0.150	0.039	Luengo-Fernandez et al (2013a)¹⁹
Other events
Other ICH	2880	440	0.700	0.093	Luengo-Fernandez et al (2013a,b) and Department of Health (2017)^19–21
Cost and disutility of CRNM	473	70	−0.058	0.017
Cost and disutility of GI bleed	856	70	−0.151	0.040
Cost and disutility of other ECH	2118	117	−0.151	0.040
Infection (related to ICM)	757	297	–		Department of Health (2017)²¹
Health states before any event
Starting utility and No-AF	–		0.820	0.008	Data on file, Medtronic 2018
Disutility for presence of AF	–		−0.014	0.019	Luengo-Fernandez et al (2013a)¹⁹
Post-stroke health states (per cycle)
Postmild stroke (IS or HS)	594	452	0.727	0.012	Luengo-Fernandez et al (2013a,b)^{19 20}‡
Post-moderate stroke (IS or HS)	1158	1007	0.582	0.035
Post-severe stroke (IS or HS)	1759		0.397	0.065
Disutility for recurrent (secondary) stroke (post-acute period)	–		−0.068	0.024	Luengo-Fernandez et al (2013a,b)^{19 20}
One-time intervention costs
ICM acquisition and insertion	1426	1129	–		Department of Health (2017)²¹
ICM removal	757	297	–		Department of Health (2017)²¹
Monitoring and follow-up (per cycle)
ICM	26.75		–		Department of Health (2017)²¹
24 hours Holter monitoring	37.88		–		Department of Health (2013)³²†
Drug costs (per cycle)
Aspirin	6.02		–		MIMS (2018)³³
Warfarin	5.71		–		MIMS (2018)³³
Warfarin INR monitoring	66.60		–		Dorian et al (2014)¹⁴ and Lip et al (2014)¹⁵§
NOAC*	159.43		–		MIMS (2018)³³

Open in a new tab

*NOAC drug cost was assumed to be the average of dabigatran, rivaroxaban, apixaban, and edoxaban

†Unit costs were inflated from 2013 to 2016/2017 values.

‡Unit costs were inflated from 2008/2009 to 2016/2017 values.

§Unit costs were inflated from 2014 to 2016/2017.

AF, atrial fibrillation;ECH, extracranial haemorrhage;GI, gastrointestinal;HS, haemorrhagic stroke;ICH, intracranial haemorrhage;ICM, insertable cardiac monitor;INR, international normalised ratio;IS, ischaemic stroke; NOAC, new oral anticoagulant; SoC, standard of care.

Resource use and costs

ICM device costs

The model accounted for one-time costs associated with inserting the ICM and subsequently removing it after battery expiry (assumed 3 years after insertion). Per cycle, costs were applied for ICM patients to cover visiting a healthcare professional if AF was detected, as well as regular ICM diagnostics, interrogation and unscheduled device-related visits. Unscheduled visit frequency was based on rates in the REVEAL AF trial. Patients with undetected AF continued SoC after their ICM was removed. There was also a risk (2.9%) of unplanned ICM removal before 3 years due to a range of clinical, technical or personal factors (Medtronic data on file).

Other costs

OAC treatment costs were estimated as an average of all European Medicines Agency (EMA) licensed NOACs: apixaban, dabigatran, edoxaban and rivaroxaban (see online supplementary file 7).

Acute events, such as strokes and bleeds, were associated with high short-term costs. When they resulted in permanent health consequences, ongoing costs were attached to being in a ‘post-stroke’ health state. Health state and event costs are summarised in table 3.

SoC costs and diagnostic yield assumptions

The REVEAL AF study did not contain information about SoC monitoring costs and diagnostic yield. We assumed that patients whose AF risk matched the REVEAL AF trial could be reasonably expected to receive a 24 hours Holter monitor once per year. Holter monitor costs were assumed to be captured by the UK NHS reference cost for ECG monitoring and stress testing.²¹

Relative diagnostic yield of ICM versus SoC was defined by an estimated HR of 33.9 (95% CI 13.2 to NE), based on a comparison of AF monitoring strategies in patients at high risk of AF and stroke, using REVEAL AF clinical trial data.²² After ICM explantation, we assumed that patients would be followed up and detected with AF according to SoC-specific risks.

Analyses

An incremental cost-effectiveness ratio (ICER) was calculated for ICM versus SoC, considering QALYs and healthcare costs accumulated over the cohort lifetime. Willingness-to-pay thresholds of £20 000 and £30 000 per QALY gained were considered.⁷ Deterministic one-way sensitivity analyses were performed on all model parameters including baseline characteristics, diagnostic accuracy, treatment efficacy and safety, utility and cost values. A scenario where warfarin was given instead of NOACs was analysed, and treatment discontinuation probabilities were studied in separate analyses. A probabilistic sensitivity analysis was performed (1000 samples) with appropriate distributions fitted to model values.

Results

Base-case analysis

The base-case deterministic analysis found that ICM provided a benefit over SoC of 0.1994 QALYs at an incremental cost of £1424 across patient lifetime and led to 4.8 fewer strokes per 100 patients (table 4). The base-case ICER for ICM versus SoC was £7140 per QALY gained, suggesting ICM is a cost-effective intervention for use in the UK NHS. The number of ICMs needed to prevent one stroke was 21 and to cause a major bleed was 37.

Table 4.

Base-case results

	SoC	ICM	Difference
Deterministic analysis
Total costs	£11 936	£13 360	£1424
Total IS per 100 patients	42.38	37.55	−4.83
QALYs	6.304	6.503	0.199
Life years	8.825	9.074	0.249
Probabilistic sensitivity analysis (average 95% CrI)
Total costs	£12 229 (£9720 to £15 087)	£14 415 (£10 945 to £20 350)	£2186 (£1225 to £5263)
Total IS per 100 patients	41.71 (32.11 to 48.75)	37.43 (31.46 to 43.73)	−4.29 (−5.03 to −0.65)
QALYs	6.314 (5.957 to 6.718)	6.491 (6.172 to 6.814)	0.177 (0.095 to 0.215)
Life years	8.852 (8.422 to 9.330)	9.073 (8.718 to 9.407)	0.221 (0.077 to 0.295)

Open in a new tab

CrI, credible interval;ICM, insertable cardiac monitor;IS, ischaemic stroke;QALYs, quality-adjusted life years;SoC, standard of care.

Incremental benefits and costs were estimated for 3 years of ICM monitoring. ICM monitoring had higher initial costs compared with SoC; it was also associated with slightly higher health state and bleed-related costs. However, by reducing the rates of IS events, use of ICMs generated cost-savings both from IS event costs as well as post-stroke health state costs (total stroke-related costs for ICM were £3783 versus £4270 for SoC).

The probabilistic sensitivity analysis showed that differences in the costs and benefits between strategies were statistically significant (table 4). The ICM strategy had a 77.4% probability of being more cost-effective at a threshold of £20 000 per QALY gained; that figure rose to 86.4% at a threshold of £30 000. The associated cost-effectiveness acceptability curve is presented in the online supplementary file 8.

Subgroup analysis

The base-case analysis modelled a distribution of CHADS₂ scores matching the REVEAL AF study population, with an average value of 2.94.⁵

The table 5 shows total costs, QALYs and ICER for SoC and ICM calculated separately by CHADS₂ score subgroups. When the analysis was carried out only in patients with a CHADS₂ score of 2, the ICER for ICM versus SoC was higher compared with the base-case analysis. In patients with a CHADS₂ score of 3, the ICER was closer to the base-case analysis because CHADS₂=3 was similar to the average in the base-case analysis. In patients with higher risk CHADS₂ scores (range 4–6), the ICER was higher than in the base-case. This increase can be attributed to the lower AF detection rates observed in the REVEAL AF trial for the CHADS₂=3–4 subgroup compared with the all-patients population (base-case).

Table 5.

Sub-group analysis by CHADS₂ score and scenario analyses

Scenario description	Total Costs		Total QALYs		ICER
Scenario description	SoC	ICM	SoC	ICM	ICM versus SoC
Base-case analysis	£11 936	£13 360	6.304	6.503	£7140
Subgroup analyses*
CHADS₂ score 2	£10 654	£12 332	7.508	7.665	£10 735
CHADS₂ score 3	£12 130	£13 591	5.960	6.133	£8425
CHADS₂ score 4, 5 and 6	£11 629	£13 070	5.375	5.527	£9463
Scenario analyses
Choice of OAC=warfarin	£11 896	£12 971	6.298	6.434	£7900
Treatment discontinuation for reasons other than bleeding=0%	£11 959	£13 570	6.316	6.680	£4427
HR ICM vs SoC (diagnostic yield)=8.78³⁴	£11 836	£13 330	6.348	6.518	£8793
Monitoring costs for SoC=assume pulse check and HR of ICM versus SoC=1/24th of the Holter monitoring (scenario proposed by clinical experts)	£10 639	£12 808	6.287	6.497	£10 323
Monitoring costs for SoC=assume pulse check and base-case HR of ICM vs SoC=33.9	£10 643	£12 811	6.304	6.503	£10 874
AF episode duration lasting for≥5.5 hours†	£10 015	£11 737	6.644	6.741	£17 693
OAC uptake after AF diagnosis = 66.35%^{5 10}	£11 923	£13 516	6.302	6.445	£11 145
Time horizon=3 years	£2257	£4142	2.219	2.232	£139 742
Time horizon=5 years	£3966	£5669	3.294	3.331	£45 916
Time horizon=10 years	£7969	£9363	5.136	5.247	£12 512
Time horizon=25 years	£11 923	£13 345	6.301	6.500	£7146

Open in a new tab

*Each CHADS₂ subgroup will differ on ischaemic stroke risk, diagnostic accuracy of monitoring strategies, as well as the corresponding age and gender mix of the group in the REVEAL AF trial.

†Analyses using the alternative definition of AF episode were carried out using the REVEAL AF clinical data set (data on file, Medtronic 2018).

AF, atrial fibrillation;ICER, incremental cost-effectiveness ratio;ICM, insertable cardiac monitor;OAC, oral anticoagulation;QALY, quality-adjusted life-year;SoC, standard of care.

Scenario analysis

The table 5 also shows results for several scenarios that were deemed clinically relevant, as they addressed essential model assumptions and data inputs. When the assumed NOAC given after AF detection was substituted with warfarin, the ICER increased slightly. This was driven by an increase in costs and a decrease in total QALYs in the ICM group, both caused by the higher bleed risks of warfarin. The higher costs associated with adverse events on warfarin eclipsed any potential cost-saving brought by the lower drug acquisition cost (£5.71 per cycle for warfarin vs £159.43 for NOAC). In the scenario where OAC treatment discontinuation was only allowed in cases of bleeding (ie, patients were not allowed to discontinue for other reasons), the ICER improved, in large part due to the continued protection afforded against IS for a greater proportion of the population. Other parameters having a notable effect on the ICER (changes of greater than £5000/QALY in its value) included: only registering AF diagnosis for episodes lasting 5.5 hours or more; shortening the model time horizon to 10 years; shortening the model time horizon to 3 years (exceeded £30 000/QALY in this last scenario).

A two-way sensitivity analysis simultaneously decreasing the HR of AF detection between the ICM and SoC arms and the assumed cost of monitoring for the SoC arm showed that even when assuming a HR value that is 10% of the base case (HR=3.39) and no diagnostic cost for the SoC arm, Reveal^® is still cost-effective, with an ICER value of £18 574 per QALY gained (see online supplementary file 8).

Sensitivity analysis

Model sensitivity was tested by varying each parameter and recording the resulting ICERs. The results of these analyses are summarised in the tornado diagram in figure 3, which shows the top 10 most sensitive parameters. One of the most sensitive parameters was, as expected, the cost of the Reveal^® device and implantation procedure, which increased the ICER to over £20 000/QALY when using the upper limit of the parameter. The model is also sensitive to baseline population characteristics, such as age, antiplatelet use and prior stroke history, although to a lesser degree. Other cost assumptions, such as cost of ICM device explantation, or cost of stroke and post-stroke health states, had a significant impact on the model results. The remaining scenarios had a smaller impact on the ICER (±£2000/QALY variation around the base-case value), maintaining results well within the willingness to pay threshold.

Tornado diagram. Note: red bars reflect the incremental cost-effectiveness ratio impact of the low limit of the parameter intervals considered, while blue bars reflect the impact of the high limit value of the parameter intervals.

Discussion

Overview

Our analyses found that continuous cardiac monitoring using ICM in a high-risk population at risk of, but without AF was a cost-effective use of resources in the UK NHS setting, with the base-case ICER and all but one of the sensitivity analysis ICERs falling below the threshold used by NICE. The ICER for ICM in this model appeared lower than ICERs estimated for ICM in patients with cryptogenic stroke⁶ or unexplained syncope.²³

Sensitivity—duration of AF

The base-case model assumed that detecting an episode of AF at least 6 min in duration would warrant the commencement of anticoagulation therapy. The frequency and duration of AF can differ from patient to patient,²⁴ and if we accept the stasis-based causal mechanism between AF and stroke,² then there is merit in discussing how much AF, and how often, is enough to warrant anticoagulation.

Although multiple factors are known to be predictive of stroke in addition to the duration and frequency of AF,²⁵ our model assumption for a 6 min AF duration threshold is generally supported by findings from other trials and UK expert opinion,^26–30 if one takes into account differences in the patient risk profiles, clinical histories and management strategies in those trials.

One of our scenario analyses assumed that only patients with AF lasting longer than 5.5 hours (a figure based on the TRENDS study²⁶ had increased stroke risk and received anticoagulation; this scenario produced an ICER which was higher than base case but still well below the NICE threshold (table 5).

Anticoagulation therapy following AF diagnosis

The cost-effectiveness of a diagnostic strategy depends not only on its accuracy and cost but also the costs and benefits of timely and accurate diagnosis, which in this case derived from receipt of appropriate treatment. Two scenario analyses illustrated how the cost-effectiveness of ICM monitoring is sensitive to assumptions around the proportion who take up and the proportion who persist with appropriate treatment following AF detection. The base-case model reflects the NICE Clinical Guideline for Management of AF (CG180)⁹ in assuming all patients at high risk of stroke in whom AF is detected will start on OAC. However, in REVEAL AF, and the comparable study PREDATE AF,¹⁰ one-third of patients remained on only antiplatelet therapy even after AF diagnosis. Under this assumption, the ICER increased to £11 145/QALY but remained well below the cost-effectiveness threshold. The base case also assumed that 16% of patients, beyond those who discontinued due to major bleeding, would stop treatment each year. If adherence is improved, ICM monitoring becomes even more cost-effective.

Standard monitoring—use of Holter monitors

Our model assumed the current SoC to be a single 24 hours Holter monitor administered annually. By contrast, the NICE Clinical Guideline for AF management recommends only an opportunistic pulse check for these at-risk patients. However, current clinical practice for high-risk patients is likely to fall somewhere between opportunistic pulse checks and an annual 24 hours Holter. Our scenario analyses show that ICM is likely to represent better value to the NHS than either strategy.

Conclusions

This analysis shows that the use of an ICM is likely to be a cost-effective means of detecting incident AF and identifying candidates for oral anticoagulation, with the aim of preventing IS. This cost-effectiveness would apply in the UK setting as well as other healthcare systems that fund interventions based on clinical evidence and comparative cost-effectiveness.

Currently, ongoing research may provide clearer inputs for some of our modelling assumptions, but based on the sensitivity analyses we have conducted, the overall conclusion with respect to cost-effectiveness is unlikely to change.

Acknowledgments

The authors would like to thank Jana Tillotson for editorial support.

Footnotes

Contributors: CR, LS, AD, MQ and ST conceived the analysis. CR and LS conducted the analysis. PZ, ME, MR and KW validated the model structure, assumptions and inputs. CR and LS wrote the introduction, methods and results. ST, CR and LS wrote the discussion section. All authors provided critical feedback on the manuscript and have approved the final version.

Funding: REVEAL AF and this cost-effectiveness analysis were funded by Medtronic plc.

Competing interests: CR, LS and AD are employed by Symmetron Ltd, which received funding from Medtronic plc for this analysis. ME’s institution has received payments from Medtronic plc for ME’s participation in this analysis. KW and MR have received consultancy fees from Medtronic plc. ST, PZ and CW are employees and have equity interest in Medtronic plc. MQ was a Medtronic employee at the time of the analysis.

Patient consent for publication: Not required.

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

Data availability statement: All data relevant to the study are included in the article or uploaded as supplementary information.

References

1.Wolf PA, Abbott RD, Kannel WB. Atrial fibrillation as an independent risk factor for stroke: the Framingham study. Stroke 1991;22:983–8. 10.1161/01.STR.22.8.983 [DOI] [PubMed] [Google Scholar]
2.Kamel H, Okin PM, Elkind MSV, et al. Atrial fibrillation and mechanisms of stroke: time for a new model. Stroke; a journal of cerebral circulation 2016;47:895–900. [DOI] [PMC free article] [PubMed] [Google Scholar]
3.Strickberger SA, Ip J, Saksena S, et al. Relationship between atrial tachyarrhythmias and symptoms. Heart Rhythm 2005;2:125–31. 10.1016/j.hrthm.2004.10.042 [DOI] [PubMed] [Google Scholar]
4.Arya A, Piorkowski C, Sommer P, et al. Clinical implications of various follow up strategies after catheter ablation of atrial fibrillation. Pacing Clin Electrophysiol 2007;30:458–62. 10.1111/j.1540-8159.2007.00693.x [DOI] [PubMed] [Google Scholar]
5.Reiffel JA, Verma A, Kowey PR, et al. Incidence of previously undiagnosed atrial fibrillation using Insertable cardiac monitors in a high-risk population. JAMA Cardiology 2017;2:1120–7. 10.1001/jamacardio.2017.3180 [DOI] [PMC free article] [PubMed] [Google Scholar]
6.Diamantopoulos A, Sawyer LM, Lip GYH, et al. Cost-effectiveness of an insertable cardiac monitor to detect atrial fibrillation in patients with cryptogenic stroke. International Journal of Stroke 2016;11:302–12. 10.1177/1747493015620803 [DOI] [PubMed] [Google Scholar]
7.National Institute for Health and Care Excellence Guide to the methods of technology appraisal. London: National Institute for Health and Care Excellence, 2013. [PubMed] [Google Scholar]
8.Hindricks G, Pokushalov E, Urban L, et al. Performance of a new Leadless implantable cardiac monitor in detecting and quantifying atrial fibrillation results of the Xpect trial. Circ Arrhythm Electrophysiol 2010;3:141–7. 10.1161/CIRCEP.109.877852 [DOI] [PubMed] [Google Scholar]
9.National Institute for Health and Care Excellence Atrial fibrillation: management. Clinical guideline [CG180], 2014. [PubMed] [Google Scholar]
10.Nasir JM, Pomeroy W, Marler A, et al. Predicting determinants of atrial fibrillation or flutter for therapy elucidation in patients at risk for thromboembolic events (PREDATE AF) study. Heart Rhythm 2017;14:955–61. 10.1016/j.hrthm.2017.04.026 [DOI] [PubMed] [Google Scholar]
11.Tawfik A, Bielecki J, Krahn M, et al. Systematic review and network meta-analysis of stroke prevention treatments in patients with atrial fibrillation. Clinical pharmacology : advances and applications 2016;8:93–107. 10.2147/CPAA.S105165 [DOI] [PMC free article] [PubMed] [Google Scholar]
12.Gage BF, van Walraven C, Pearce L, et al. Selecting patients with atrial fibrillation for anticoagulation: stroke risk stratification in patients taking aspirin. Circulation 2004;110:2287–92. [DOI] [PubMed] [Google Scholar]
13.Pisters R, Lane DA, Marin F, et al. Stroke and thromboembolism in atrial fibrillation. Circulation Journal 2012;76:2289–304. 10.1253/circj.CJ-12-1036 [DOI] [PubMed] [Google Scholar]
14.Dorian P, Kongnakorn T, Phatak H, et al. Cost-effectiveness of apixaban vs. current standard of care for stroke prevention in patients with atrial fibrillation. European Heart Journal 2014;35:1897–906. 10.1093/eurheartj/ehu006 [DOI] [PMC free article] [PubMed] [Google Scholar]
15.Lip GYH, Kongnakorn T, Phatak H, et al. Cost-effectiveness of apixaban versus other new oral anticoagulants for stroke prevention in atrial fibrillation. Clinical Therapeutics 2014;36:192–210. 10.1016/j.clinthera.2013.12.011 [DOI] [PubMed] [Google Scholar]
16.Claassen DO, Kazemi N, Zubkov AY, et al. Restarting anticoagulation therapy after warfarin-associated intracerebral hemorrhage. Archives of Neurology 2008;65:1313–8. 10.1001/archneur.65.10.1313 [DOI] [PubMed] [Google Scholar]
17.Sorensen SV, Dewilde S, Singer DE, et al. Cost-effectiveness of warfarin: Trial versus “real-world” stroke prevention in atrial fibrillation. American Heart Journal 2009;157:1064–73. 10.1016/j.ahj.2009.03.022 [DOI] [PubMed] [Google Scholar]
18.Office for National Statistics Mortality statistics: deaths: underlying cause, sex and age-group, 2014: chapter IX. Diseases of the circulatory system. England and Wales, 2014. Available: http://www.ons.gov.uk/ons/rel/vsob1/mortality-statistics-deaths-registered-in-england-and-wales-series-dr-/2012/index.html
19.Luengo-Fernandez R, Gray AM, Bull L, et al. Quality of life after TIA and stroke: ten-year results of the Oxford Vascular Study. Neurology 2013;81:1588–95. 10.1212/WNL.0b013e3182a9f45f [DOI] [PMC free article] [PubMed] [Google Scholar]
20.Luengo-Fernandez R, Paul NL, Gray AM, et al. Population-based study of disability and institutionalization after transient ischemic attack and stroke: 10-year results of the Oxford Vascular Study. Stroke; a journal of cerebral circulation 2013;44:2854–61. [DOI] [PMC free article] [PubMed] [Google Scholar]
21.Department of Health NHS reference costs 2016-2017, 2017. Available: https://improvement.nhs.uk/resources/reference-costs/
22.Reiffel JA, Verma A, Kowey P, et al. A comparison of atrial fibrillation monitoring strategies in patients at high risk for atrial fibrillation and stroke: results from the reveal AF study. J Am Coll Cardiol 2018;71 10.1016/S0735-1097(18)30815-5 [DOI] [Google Scholar]
23.Davis S, Westby M, Pitcher D, et al. Implantable loop recorders are cost-effective when used to investigate transient loss of consciousness which is either suspected to be arrhythmic or remains unexplained. Europace 2012;14:402–9. 10.1093/europace/eur343 [DOI] [PubMed] [Google Scholar]
24.Martinek M, Aichinger J, Nesser H-J, et al. New insights into long-term follow-up of atrial fibrillation ablation: full disclosure by an implantable pacemaker device. J Cardiovasc Electrophysiol 2007;18:818–23. 10.1111/j.1540-8167.2007.00883.x [DOI] [PubMed] [Google Scholar]
25.Botto GL, Padeletti L, Santini M, et al. Presence and duration of atrial fibrillation detected by continuous monitoring: crucial implications for the risk of thromboembolic events. J Cardiovasc Electrophysiol 2009;20:241–8. 10.1111/j.1540-8167.2008.01320.x [DOI] [PubMed] [Google Scholar]
26.Glotzer TV, Daoud EG, Wyse DG, et al. The relationship between daily atrial tachyarrhythmia burden from implantable device diagnostics and stroke risk. Circ Arrhythm Electrophysiol 2009;2:474–80. 10.1161/CIRCEP.109.849638 [DOI] [PubMed] [Google Scholar]
27.Healey JS, Connolly SJ, Gold MR, et al. Subclinical atrial fibrillation and the risk of stroke. N Engl J Med 2012;366:120–9. 10.1056/NEJMoa1105575 [DOI] [PubMed] [Google Scholar]
28.National Institute for Health and Care Excellence Reveal LINQ insertable cardiac monitor to detect atrial fibrillation after cryptogenic stroke. Medtech innovation briefing [MIB141]. London: National Institute for Health and Care Excellence, 2018. [Google Scholar]
29.Healey JS, Alings M, Ha A, et al. Subclinical atrial fibrillation in older patients. Circulation 2017;136:1276–83. 10.1161/CIRCULATIONAHA.117.028845 [DOI] [PubMed] [Google Scholar]
30.Wong JA, Conen D, Van Gelder IC, et al. Progression of Device-Detected Subclinical Atrial Fibrillation and the Risk of Heart Failure. J Am Coll Cardiol 2018;71:2603–11. 10.1016/j.jacc.2018.03.519 [DOI] [PubMed] [Google Scholar]
31.Ariesen MJ, Claus SP, Rinkel GJE, et al. Risk factors for intracerebral hemorrhage in the general population. Stroke 2003;34:2060–5. 10.1161/01.STR.0000080678.09344.8D [DOI] [PubMed] [Google Scholar]
32.Department of Health NHS reference costs 2012-2013, 2013. Available: https://www.gov.uk/government/publications/nhs-reference-costs-2012-to-2013
33.Monthly Index of Medical Specialities (MIMS) Online version, 2018. Available: http://www.mims.co.uk/
34.Sanna T, Diener H-C, Passman RS, et al. Cryptogenic stroke and underlying atrial fibrillation. N Engl J Med 2014;370:2478–86. 10.1056/NEJMoa1313600 [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary data

openhrt-2019-001037supp001.docx^{(550.9KB, docx)}

[R1] 1.Wolf PA, Abbott RD, Kannel WB. Atrial fibrillation as an independent risk factor for stroke: the Framingham study. Stroke 1991;22:983–8. 10.1161/01.STR.22.8.983 [DOI] [PubMed] [Google Scholar]

[R2] 2.Kamel H, Okin PM, Elkind MSV, et al. Atrial fibrillation and mechanisms of stroke: time for a new model. Stroke; a journal of cerebral circulation 2016;47:895–900. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R3] 3.Strickberger SA, Ip J, Saksena S, et al. Relationship between atrial tachyarrhythmias and symptoms. Heart Rhythm 2005;2:125–31. 10.1016/j.hrthm.2004.10.042 [DOI] [PubMed] [Google Scholar]

[R4] 4.Arya A, Piorkowski C, Sommer P, et al. Clinical implications of various follow up strategies after catheter ablation of atrial fibrillation. Pacing Clin Electrophysiol 2007;30:458–62. 10.1111/j.1540-8159.2007.00693.x [DOI] [PubMed] [Google Scholar]

[R5] 5.Reiffel JA, Verma A, Kowey PR, et al. Incidence of previously undiagnosed atrial fibrillation using Insertable cardiac monitors in a high-risk population. JAMA Cardiology 2017;2:1120–7. 10.1001/jamacardio.2017.3180 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R6] 6.Diamantopoulos A, Sawyer LM, Lip GYH, et al. Cost-effectiveness of an insertable cardiac monitor to detect atrial fibrillation in patients with cryptogenic stroke. International Journal of Stroke 2016;11:302–12. 10.1177/1747493015620803 [DOI] [PubMed] [Google Scholar]

[R7] 7.National Institute for Health and Care Excellence Guide to the methods of technology appraisal. London: National Institute for Health and Care Excellence, 2013. [PubMed] [Google Scholar]

[R8] 8.Hindricks G, Pokushalov E, Urban L, et al. Performance of a new Leadless implantable cardiac monitor in detecting and quantifying atrial fibrillation results of the Xpect trial. Circ Arrhythm Electrophysiol 2010;3:141–7. 10.1161/CIRCEP.109.877852 [DOI] [PubMed] [Google Scholar]

[R9] 9.National Institute for Health and Care Excellence Atrial fibrillation: management. Clinical guideline [CG180], 2014. [PubMed] [Google Scholar]

[R10] 10.Nasir JM, Pomeroy W, Marler A, et al. Predicting determinants of atrial fibrillation or flutter for therapy elucidation in patients at risk for thromboembolic events (PREDATE AF) study. Heart Rhythm 2017;14:955–61. 10.1016/j.hrthm.2017.04.026 [DOI] [PubMed] [Google Scholar]

[R11] 11.Tawfik A, Bielecki J, Krahn M, et al. Systematic review and network meta-analysis of stroke prevention treatments in patients with atrial fibrillation. Clinical pharmacology : advances and applications 2016;8:93–107. 10.2147/CPAA.S105165 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R12] 12.Gage BF, van Walraven C, Pearce L, et al. Selecting patients with atrial fibrillation for anticoagulation: stroke risk stratification in patients taking aspirin. Circulation 2004;110:2287–92. [DOI] [PubMed] [Google Scholar]

[R13] 13.Pisters R, Lane DA, Marin F, et al. Stroke and thromboembolism in atrial fibrillation. Circulation Journal 2012;76:2289–304. 10.1253/circj.CJ-12-1036 [DOI] [PubMed] [Google Scholar]

[R14] 14.Dorian P, Kongnakorn T, Phatak H, et al. Cost-effectiveness of apixaban vs. current standard of care for stroke prevention in patients with atrial fibrillation. European Heart Journal 2014;35:1897–906. 10.1093/eurheartj/ehu006 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R15] 15.Lip GYH, Kongnakorn T, Phatak H, et al. Cost-effectiveness of apixaban versus other new oral anticoagulants for stroke prevention in atrial fibrillation. Clinical Therapeutics 2014;36:192–210. 10.1016/j.clinthera.2013.12.011 [DOI] [PubMed] [Google Scholar]

[R16] 16.Claassen DO, Kazemi N, Zubkov AY, et al. Restarting anticoagulation therapy after warfarin-associated intracerebral hemorrhage. Archives of Neurology 2008;65:1313–8. 10.1001/archneur.65.10.1313 [DOI] [PubMed] [Google Scholar]

[R17] 17.Sorensen SV, Dewilde S, Singer DE, et al. Cost-effectiveness of warfarin: Trial versus “real-world” stroke prevention in atrial fibrillation. American Heart Journal 2009;157:1064–73. 10.1016/j.ahj.2009.03.022 [DOI] [PubMed] [Google Scholar]

[R18] 18.Office for National Statistics Mortality statistics: deaths: underlying cause, sex and age-group, 2014: chapter IX. Diseases of the circulatory system. England and Wales, 2014. Available: http://www.ons.gov.uk/ons/rel/vsob1/mortality-statistics-deaths-registered-in-england-and-wales-series-dr-/2012/index.html

[R19] 19.Luengo-Fernandez R, Gray AM, Bull L, et al. Quality of life after TIA and stroke: ten-year results of the Oxford Vascular Study. Neurology 2013;81:1588–95. 10.1212/WNL.0b013e3182a9f45f [DOI] [PMC free article] [PubMed] [Google Scholar]

[R20] 20.Luengo-Fernandez R, Paul NL, Gray AM, et al. Population-based study of disability and institutionalization after transient ischemic attack and stroke: 10-year results of the Oxford Vascular Study. Stroke; a journal of cerebral circulation 2013;44:2854–61. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R21] 21.Department of Health NHS reference costs 2016-2017, 2017. Available: https://improvement.nhs.uk/resources/reference-costs/

[R22] 22.Reiffel JA, Verma A, Kowey P, et al. A comparison of atrial fibrillation monitoring strategies in patients at high risk for atrial fibrillation and stroke: results from the reveal AF study. J Am Coll Cardiol 2018;71 10.1016/S0735-1097(18)30815-5 [DOI] [Google Scholar]

[R23] 23.Davis S, Westby M, Pitcher D, et al. Implantable loop recorders are cost-effective when used to investigate transient loss of consciousness which is either suspected to be arrhythmic or remains unexplained. Europace 2012;14:402–9. 10.1093/europace/eur343 [DOI] [PubMed] [Google Scholar]

[R24] 24.Martinek M, Aichinger J, Nesser H-J, et al. New insights into long-term follow-up of atrial fibrillation ablation: full disclosure by an implantable pacemaker device. J Cardiovasc Electrophysiol 2007;18:818–23. 10.1111/j.1540-8167.2007.00883.x [DOI] [PubMed] [Google Scholar]

[R25] 25.Botto GL, Padeletti L, Santini M, et al. Presence and duration of atrial fibrillation detected by continuous monitoring: crucial implications for the risk of thromboembolic events. J Cardiovasc Electrophysiol 2009;20:241–8. 10.1111/j.1540-8167.2008.01320.x [DOI] [PubMed] [Google Scholar]

[R26] 26.Glotzer TV, Daoud EG, Wyse DG, et al. The relationship between daily atrial tachyarrhythmia burden from implantable device diagnostics and stroke risk. Circ Arrhythm Electrophysiol 2009;2:474–80. 10.1161/CIRCEP.109.849638 [DOI] [PubMed] [Google Scholar]

[R27] 27.Healey JS, Connolly SJ, Gold MR, et al. Subclinical atrial fibrillation and the risk of stroke. N Engl J Med 2012;366:120–9. 10.1056/NEJMoa1105575 [DOI] [PubMed] [Google Scholar]

[R28] 28.National Institute for Health and Care Excellence Reveal LINQ insertable cardiac monitor to detect atrial fibrillation after cryptogenic stroke. Medtech innovation briefing [MIB141]. London: National Institute for Health and Care Excellence, 2018. [Google Scholar]

[R29] 29.Healey JS, Alings M, Ha A, et al. Subclinical atrial fibrillation in older patients. Circulation 2017;136:1276–83. 10.1161/CIRCULATIONAHA.117.028845 [DOI] [PubMed] [Google Scholar]

[R30] 30.Wong JA, Conen D, Van Gelder IC, et al. Progression of Device-Detected Subclinical Atrial Fibrillation and the Risk of Heart Failure. J Am Coll Cardiol 2018;71:2603–11. 10.1016/j.jacc.2018.03.519 [DOI] [PubMed] [Google Scholar]

[R31] 31.Ariesen MJ, Claus SP, Rinkel GJE, et al. Risk factors for intracerebral hemorrhage in the general population. Stroke 2003;34:2060–5. 10.1161/01.STR.0000080678.09344.8D [DOI] [PubMed] [Google Scholar]

[R32] 32.Department of Health NHS reference costs 2012-2013, 2013. Available: https://www.gov.uk/government/publications/nhs-reference-costs-2012-to-2013

[R33] 33.Monthly Index of Medical Specialities (MIMS) Online version, 2018. Available: http://www.mims.co.uk/

[R34] 34.Sanna T, Diener H-C, Passman RS, et al. Cryptogenic stroke and underlying atrial fibrillation. N Engl J Med 2014;370:2478–86. 10.1056/NEJMoa1313600 [DOI] [PubMed] [Google Scholar]

PERMALINK

Cost-effectiveness of an insertable cardiac monitor in a high-risk population in the UK

Claudia I Rinciog

Laura M Sawyer

Alexander Diamantopoulos

Mitchell S V Elkind

Matthew Reynolds

Stylianos I Tsintzos

Paul D Ziegler

Maria E Quiroz

Claudia Wolff

Klaus K Witte

Series information

Abstract

Objective

Methods

Results

Conclusions

Key questions.

What is already known about this subject?

What does this study add?

How might this impact on clinical practice?

Introduction

Methods

Model structure

Figure 1.

Input parameters

Population

Probabilities

Table 1.

AF incidence, detection and subsequent treatment

Figure 2.

Ischaemic stroke risk and severity

Table 2.

Bleeding events and anticoagulation therapy changes

Mortality

Health-related QOL

Table 3.

Resource use and costs

ICM device costs

Other costs

SoC costs and diagnostic yield assumptions

Analyses

Results

Base-case analysis

Table 4.

Subgroup analysis

Table 5.

Scenario analysis

Sensitivity analysis

Figure 3.

Discussion

Overview

Sensitivity—duration of AF

Anticoagulation therapy following AF diagnosis

Standard monitoring—use of Holter monitors

Conclusions

Acknowledgments

Footnotes

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

Similar articles

Cited by other articles

Links to NCBI Databases