©  R A D C L I F F E  VA S C U L A R  2 0 2 0 Access at: www.VERjournal.com

Peripheral Artery Disease

Wearable technology refers to the broad category of compact electronic 

devices that can be incorporated into clothing or accessories.1 These 

devices are used in the clinical and non-clinical environment and they 

offer multiple applications that help maintain physiological and 

psychological wellbeing.2 Wearable technologies not only facilitate self-

tracking for the consumer but also allows for remote monitoring and 

analysis by a third party, such as a healthcare provider. 

The Internet of Things is a network of real-world objects that have the 

ability to communicate data and sense the status of each object and 

the surrounding environment.3 Through the combined use of wearable 

devices and Internet of Things technology, patients and healthcare 

providers may be able to track, monitor and analyse various clinically 

relevant measurements. This could lead to real-time monitoring of 

disease progression as well as treatment adherence. 

This concept feeds into the premise of telemonitoring, which is defined 

as the use of telecommunication devices to remotely monitor patients 

at a distance.4  Of note, telemonitoring is broadly synonymous with 

biotelemetry, which involves the transmission of health data from one 

location to another where the data can be  interpreted and used to 

affect healthcare decision-making.4,5 Telemonitoring is useful in 

collecting biological, environmental or physiological data in a remote 

setting when direct observation is not possible.5 Common clinically 

pertinent measurements such as blood pressure (BP), blood glucose 

and lung function have been successfully tracked using telemonitoring 

technologies.6–10 The use of telemonitoring allows patients to be 

managed at home, thereby helping to overcome barriers concerning 

access to healthcare, such as travel, time and costs. 

These technological advancements may prove useful in the 

management of cardiovascular disease (CVD). CVD is a major global 

health burden and accounts for a significant proportion of hospital 

admissions, as well as up to one-third of all deaths globally.11 However, 

given the importance of conservative management and lifestyle 

modifications, wearable technology may be able to disrupt the way in 

which medical therapy and lifestyle modification advice is delivered to 

this patient cohort. Therefore, in this review, we aim to summarise the 

current applications of wearable and telemonitoring technologies in 

facilitating the management of CVD outside the hospital setting.  

Current Wearable Technologies
The broad definition of wearable technologies encompasses a variety 

of devices, such as head-mounted displays, clothing with smart 

technology, fitness trackers, smart watches and biosensors.

Fitness trackers (activity monitors) allow the long-term daily monitoring 

of physical activity in a real-world setting and usually take the form of 

wrist bands, ankle bracelets or clip-ons. Fitness trackers use sensors 

(pedometers or accelerometers) to detect movement and are therefore 

able to measure physical activity. Electronic displays on devices allow 

quick and easy viewing of exercise progress and goals. Many devices 

are able to transfer data to computer or smartphone apps, allowing 

remote access to data. 

Abstract
Wearable devices and telemonitoring are becoming increasingly widespread in the clinical environment and have many applications in the 

tracking and maintenance of patient wellbeing. Interventions incorporating these technologies have been used with some success in patients 

with vascular disorders. Wearable fitness monitors and telemonitoring have been used in the community to mobilise patients with peripheral 

vascular disease with good results. Additionally, wearable monitors and telemonitoring have been studied for blood pressure monitoring in 

patients with hypertension. Telemonitoring interventions incorporating electronic medication trays and ingestible sensors have also been 

found to increase drug adherence in hypertensive patients and ultimately improve health outcomes. However, wearable and telemonitoring 

interventions often face problems with patient adherence, digital literacy and infrastructure. Further work needs to address these challenges 

and validate the technology before widespread implementation can occur.

Keywords
Peripheral vascular disease, wearable technology, personalised medicine, telemedicine, digital health

Disclosure: The authors have no conflicts of interest to declare. 

Received: 18 November 2019 Accepted: 2 February 2020 Citation: Vascular & Endovascular Review 2020;3:e04. DOI: https://doi.org/10.15420/ver.2019.11

Correspondence: Viknesh Sounderajah, Department of Surgery and Cancer, Imperial College London, London W2 1NY, UK. E: vs1108@imperial.ac.uk

Open Access: This work is open access under the CC-BY-NC 4.0 License which allows users to copy, redistribute and make derivative works for non-

commercial purposes, provided the original work is cited correctly.

The Role of Wearable Technologies and Telemonitoring 
in Managing Vascular Disease

Calvin Chan, Viknesh Sounderajah, Amish Acharya, Pasha Normahani, Colin Bicknell and Celia Riga

Department of Surgery and Cancer, Imperial College London, London, UK

mailto:vs1108@imperial.ac.uk
https://creativecommons.org/licenses/by-nc/4.0/legalcode


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Peripheral Artery Disease

Luley et al. used AiperMotion 440 (Aipermon) fitness trackers as part of 

an intervention to increase physical activity in patients with metabolic 

syndrome and found significant improvements in weight loss and 

markers of the metabolic syndrome.12 In a randomised controlled trial, 

Frederix et al. used triaxial accelerometers (Yorbody) to monitor 

physical activity and set daily step-count prescriptions for patients 

with coronary artery disease enrolled in hospital-based cardiac 

rehabilitation.13 This study found a significant improvement in lung 

function assessments and a trend towards fewer rehospitalisations in 

the intervention group. Kirk et al. conducted a meta-analysis examining 

the use of wearable devices to alter physical activity behaviour in 

adults with chronic cardiometabolic disease and found a positive 

impact on physical health.14 

Smart watches have many of the same functions as smartphones, such 

as mobile applications, internet connectivity and GPS.15 Similar to 

fitness trackers, smart watches can also incorporate movement and 

exercise sensing functions, but their functionality is expanding. For 

example the Apple Watch (Apple) is currently being validated by clinical 

trials for detection of AF and other abnormal heart rhythms.16

Wearable biosensors are attached to the body for long continuous 

periods of time and have diagnostic and monitoring applications. The 

Wearable Biosensor (Philips Medical Systems) is a lightweight, wireless 

self-adhesive biosensor that can detect vital signs – ECG, respiratory 

rate, skin temperature – and movement data – posture, fall detection, 

step count. A study conducted by Braem et al. found that the use of this 

wearable device as a tool for screening activity levels in patients 

undergoing transcatheter aortic valve implantation was feasible, but 

noted some concerns regarding the reliability of the data collection.17 

Continuous glucose monitoring can provide real-time blood glucose 

data otherwise unobtainable by conventional intermittent sampling. 

GlucoWatch (Cygnus) is a non-invasive wearable continuous glucose 

monitor that extracts and samples glucose through intact skin via 

reverse iontophoresis.18 A validation study by Tierney et al. found blood 

glucose readings from the device were clinically acceptable. However, 

a randomised trial by Chase et al. found no improvement in glycaemic 

control with the GlucoWatch, which was, in part, attributed to poor 

device adherence due to skin irritation.18,19

Peripheral Artery Disease Management
Wearable devices with the ability to monitor movement may be 

particularly useful in the management of patients with peripheral artery 

disease (PAD). PAD is a debilitating condition that results in significant 

walking impairment and poor quality of life.20 Current recommended 

first-line management for PAD is supervised exercise therapy, with 

patient mobilisation crucial to prevent disease progression and reduce 

hospital admissions.21,22 Despite this, patients often face challenges in 

accessing therapy due to cost, travel and time constraints. This 

contributes to the low uptake and adherence with such programmes.23,24 

Several studies have investigated the efficacy of home-based exercise 

programmes incorporating fitness trackers and telemonitoring as an 

alternative to supervised exercise (Table 1).25–33 Duscha et al. used 

wrist-worn commercially available fitness trackers (FitBit Charge, FitBit) 

to monitor daily physical activity and set exercise prescriptions based 

increasing patients’ step count each day.27 Patients wore fitness 

trackers continuously during waking hours and daily step count was 

synchronised with smartphones where it could be remotely viewed. 

This allowed investigators to not only monitor physical activity, but also 

offer personalised feedback via phone calls. Patients using the fitness 

tracker intervention were found to have significant improvement in 

claudication distance, maximum walking distance and steps walked per 

day, compared with baseline. 

Similarly, Normahani et al. incorporated the Nike+ FuelBand (Nike) 

fitness tracker as part of a home-based exercise intervention for 

patients with PAD.28 Instead of setting exercise prescriptions using step 

count, ‘fuel points’ were used, which measure overall activity and 

movement. Online accounts on the Nike+ website allowed activity data 

to be reviewed at follow-up visits and exercise prescriptions could be 

programmed into patient devices. The study found significant increases 

in walking ability and quality of life in patients using the device, 

compared with those attending a weekly 1-hour supervised exercise 

session over a 12-month period. 

In addition to using the AE120XL pedometer (Accusplit) to track daily 

physical activity and weekly phone consultations, Mays et al. 

incorporated an element of coaching into their study.30 This allowed 

them to identify local barriers and encourage exercise adherence. This 

involved an assessment of a patient’s local area using Google Street 

View to identify walking routes and community resources, such as 

benches on which to rest. Moreover, they identified potential barriers to 

walking, such as discontinuous pavements.30,34 This resulted in 

significant improvements in walking ability for the intervention group 

compared with baseline and usual care. 

The use of smartphone applications may also be beneficial for the 

remote monitoring and management of PAD. Ata et al. developed 

VascTrac, an Apple smartphone app that enabled remote collection of 

medical and physical activity data.35 VascTrac is able to record 

measures of daily physical activity (steps walked, distance walked, 

flights of stairs climbed and maximum continuous number of steps) 

using the built-in accelerometer in Apple smartphones. Patients were 

sent notifications through the app to perform twice-weekly 6-minute 

walk tests which allows tracking of changes in walking ability. Study 

results are yet to be published. 

Blood Pressure Monitoring
Hypertension is a well-known risk factor for CVD.21 Environmental 

factors can often limit the usefulness of conventional BP measurements 

because of phenomena such as white-coat, masked and nocturnal 

hypertension.36 Home measurement is a superior method of 

determining BP and wearable devices are well established for this 

purpose.37 Apart from traditional oscillometry-based BP measurement 

(involving an inflatable cuff), wearable devices also use other non-

invasive methods of eliciting measures of BP such as tonometry, 

volume clamp, pulse wave velocity and pulse transit time (Table 2).38

The BPro (Healthstats) is a cuffless, wrist-bound BP measurement 

system that works via arterial applanation tonometry. The wrist monitor 

incorporates a small protruding force sensor that rests over the radial 

artery and captures the arterial pulse waveform.39 The device requires 

initial calibration to bronchial BP using a standard oscillometry-based 

BP monitor. In a validation study, the device was found to meet the 

accuracy criteria for systolic and diastolic BP in both European Society 

of Hypertension protocol and Association for the Advancement of 

Medical Instrumentation (AAMI) standards under stationary conditions.40 

However, in a study comparing accuracy of the BPro against intra-

arterial BP measurement in post-operative patients, there were 



Wearable Technologies and Telemonitoring for Vascular Disease

VA S C U L A R  &  E N D O VA S C U L A R  R E V I E W

Table 1: Characteristics and Main Findings of Studies Incorporating Wearable Devices for Management of  
Peripheral Artery Disease

Study Study 
Design

Study 
Duration

Study 
Size (n)

Wearable  
Device

Patient 
Population

Wearable  
Intervention

Additional  
Interventions

Control Main Findings

Dacha et al. 
201827

RCT 12 weeks 20 FitBit Charge Exercise 
limited by IC, 
ABPI <0.9

Daily walking 
prescription, 
increasing every 4 
weeks

Electronic PAD 
information, 
weekly tips, 
phone 
consultations

Physician 
advice,  
PAD book

Significant improvement in 
walking ability and VO

2 
max, 

increase in steps per day 
and exercise intensity

Endicott et 
al. 201925

PS 6 months 49 FitBit One Veterans, 
symptomatic 
IC

Daily walking 
prescription

Clinic 
consultations 
every 4 weeks

NA Significant increase in steps 
per day

Gardner et 
al. 201132

RCT 12 weeks 119 StepWatch3  
(modus)

Symptomatic 
IC, ABPI <0.9

Walking three 
times per week, 
increasing 
duration biweekly

15 min 
consultation  
biweekly

3-month SET, 
physician 
advice

Significant improvement in 
walking ability, walking 
speed, QoL and VO

2 
max

Gardner et 
al. 201431

RCT 12 weeks 180 StepWatch3 
(modus)

Symptomatic 
IC, ABPI <0.9

Walking three 
times per week, 
increasing 
duration 
evert 4 weeks

15 min 
consultation 
every 4 weeks

3-month SET, 
light  
resistance 
training

Significant improvement in 
walking ability, walking 
speed, QoL and VO

2 
max

Mays et al. 
2015,30 
201531

RCT 14 weeks 25 Accusplit 
AE120XL

Symptomatic 
IC, previous 
endovascular 
therapy

Walking three 
times  
per week

Initial 2-week SET 
(3× per week), 
weekly phone 
consultations

Physician 
advice 

Significant improvement in 
walking ability.

McDermott 
et al. 201826

RCT 9 months 200 FitBit Zip ABPI <0.9 Exercise five times 
per week, 
increasing duration 
and intensity

Four initial SET 
sessions then 
weekly phone 
consultations

No 
intervention

No improvement in walking 
ability or QoL. Significant 
improvement in exercise 
frequency 

Nicolaï et al. 
201033

RCT 12 months 304 Pam Personal  
Activity 
Monitor

Stage II PAD Walking feedback 
and 
encouragement

SET (60–90 mins 
per week), WAM 
scores used to 
give feedback on 
walking effort 
outside SET

SET (2–3× per 
week), 
physician 
advice

Significant improvement in 
walking ability and QoL. No 
difference compared with 
SET only

Normahani 
et al. 201828

RCT 12 months 37 Nike+ 
FuelBand

Symptomatic 
IC, stenosis 
on 
ultrasound

Daily activity 
targets: ‘fuel 
points’

SET (1 hour/
week), clinic 
consultations at 3, 
6 and 12 months

3-month SET 
(1 hour per 
week)

Significant improvement in 
walking ability and QoL

Tew et al. 
201529

RCT 6 weeks 23 Yamax SW-200 
Digiwalker

Clinically 
diagnosed IC

Walking 
self-regulation, 
goal to reach  
>7,500 steps/day

Structured IC 
education 
(SEDRIC), phone 
consultation at 2 
weeks

PAD 
information 
leaflet

Significant improvement in 
walking ability and QoL. No 
change in steps/day

ABPI = ankle–brachial pressure index; IC = intermittent claudication; NA = not available; PAD = peripheral artery disease; PS = prospective study; QoL = quality of life; RCT = randomised 
controlled trial; SEDRIC which is Structured EDucation for Rehabilitation in Intermittent Claudication; SET = supervised exercise therapy; WAM = wearable activity monitor.

Table 2: Characteristics and Validation Study Findings for Wearable Blood Pressure Monitoring Devices

Wearable Device Calibration
Measurements 
Provided

Method of 
Measurement

Level of Validation

BPro (MedTach) Required with validated 
oscillometry-based device

SBP, DBP, rAIx Applanation tonometry • Meets AAMI and ESH standards of accuracy compared 
with sphygmomanometer under stationary conditions.40

• Inaccurate agreement in SBP against intra-arterial 
measurement in post-operative patients; device 
affected by slight movement.41

• Fair agreement with a brachial cuff-based device under 
ambulatory conditions; volunteers instructed to hold 
still during measurements.39 

• Inaccuracies in estimating rAIx.41

Seismo-Watch Required with validated 
oscillometry-based device

SBP, DBP Pulse transit time Acceptable DBP measurements when volunteers were 
static.45



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Peripheral Artery Disease

significant inaccuracies according to AAMI standards in systolic and 

mean BP between the methods, which was attributed to patient 

movement.41 A 24-hour study comparing the BPro to conventional arm-

bound oscillometry-based BP monitoring in 50 normotensive and 

prehypertensive volunteers found fair agreement between the two 

devices.39 However, during BP measurements the volunteers were 

asked to keep still and the BPro was unable to obtain almost 50% of the 

scheduled measurements.39

In addition to BP measurement, radial augmentation index (rAIx) can be 

calculated from radial wave pulse measurements from the BPro.42 The 

rAIx has been proposed as an estimate of central BP and a useful 

parameter of vascular function and ageing.43 Although there were 

discrepancies in rAIx measured by BPro versus a reference device, 

Vardoulis et al. developed and validated a novel wrist-bound tonometer 

that produced accurate rAIx readings compared with a reference hand-

held tonometer.42,44 

The SeismoWatch is an example of a wrist-worn BP monitor that 

functions via pulse transit time.45 To obtain BP measurements, the 

watch face contains an accelerometer which is pressed for a short 

duration on the sternum to obtain a seismocardiogram and determine 

timing of left ventricular ejection. This is compared with a distal reading 

from a wrist-obtained photoplethysmogram to obtain the pulse transit 

time and, therefore, an estimate of BP.45 In a small feasibility study, the 

device was found to obtain acceptable mean and diastolic BP, but 

required subjects to perform measurements while static.45 Similarly, 

Ogink et al. investigated the feasibility of a cuffless BP monitor 

(Checkme Pro, Viatom) based on pulse transit time to measure systolic 

BP of hypertensive patients at home.46 The study found that the device 

produced reproducible BP readings and had good adherence due to its 

ease of use. However, the device was limited by its inability to measure 

diastolic BP and failure to measure BP 30% of the time. 

Boubouchairopoulou et al. validated a cuffless BP monitor (FreeScan, 

Maisense) that obtained readings via pulse transit time.47 In large 

successive feasibility and validation studies (a total of 313 patients 

were involved in the four feasibility studies), the device was found 

capable of obtaining systolic and diastolic BP readings when compared 

with a standard mercury sphygmomanometer. However, accurate 

readings required a device sensor upgrade and careful initial device 

calibration in a research setting. Further work is needed to investigate 

the validity of this prototype device in a clinical setting. 

The HeartGuide (Omron Corp) is a novel smartwatch with the ability to 

monitor BP.48 It uses the traditional oscillometry-based principle where 

the strap of the wrist-worn device acts as a BP cuff and allows BP 

measurement for up to 7 days on a single charge. It has additional 

abilities such as data synchronisation to an online account as well as 

step count and heart rate monitoring. However, this device is yet to be 

validated. 

Best Medical Therapy Compliance Monitoring
Non-adherence to medication in hypertensive patients is a 

contributing factor to poor BP control and is associated with higher 

risks of vascular events, hospitalisation and increased healthcare 

costs.49 Davidson et al. developed and validated a telemonitoring 

intervention involving electronic medication trays, Bluetooth-enabled 

BP monitors and SMS messaging.50 The electronic medication tray 

(Maya, MedMinder) reminded patients to take their dose at the 

prescribed time first with a blinking light, then a 30-minute chime and 

finally an automated phone call or SMS. Patients were reminded to 

use the Bluetooth-enabled BP monitor (UA-767PlusBT, A&D 

Engineering) via SMS, and readings were sent from the device to a 

provided smartphone and a remote data repository via cellular 

network. If BP measurements were above a predefined threshold, 

patients were instructed via phone to obtain additional measurements 

and their physician was alerted. Patients in the telemonitoring group 

had significant lower systolic and diastolic BP across the study’s 

duration and a significantly greater proportion achieved BP control. 

Frias et al. validated a system involving ingestible sensors and 

wearable sensor patches (Proteus Discover, Proteus Digital Health) 

for patients with uncontrolled hypertension and type 2 diabetes.51 

The medications of patients in the intervention group were co-

encapsulated with ingestible sensors. Once swallowed, the 

ingestible sensor would activate and send a signal to the adhesive 

sensor patch. Data from the patch was then transmitted to an online 

data repository via a smartphone app. Data could be viewed by 

patients on the mobile app and remotely by their physicians. The 

mobile app also prompted patients to take their medications at the 

prescribed times. There were significant improvements in systolic 

BP and a larger proportion of patients achieved their BP goal in the 

intervention group. In terms of diabetes, however, there was no 

significant difference in HbA
1c

 or fasting plasma glucose between 

intervention and control groups. Physicians with access to the 

online data made approximately three times more medical decisions 

per participant and patients with uncontrolled hypertension in the 

intervention group were more likely to be given a medication 

adjustment or adherence counselling. However, a comparison of 

adherence to medication could not be assessed due to the intrinsic 

design of the study. 

Table 2: Cont.

Wearable Device Calibration
Measurements 
Provided

Method of 
Measurement

Level of Validation

Checkme (Viatom) Required with validated 
oscillometry-based device

SBP Pulse transit time Good reproducibility of results but weak correlation with 
cuff-based BP monitors. Device failed to produce 
measurements 30% of the time.47

Freescan (Maisense) Required with validated 
oscillometry-based device

SBP, DBP Pulse transit time Produced valid SBP and DBP measurements that met 
AAMI accuracy standards. Required careful calibration.47

HeartGuide (Omron) Not required SBP, DBP, pulse rate, 
physical activity

Oscillometry None

AAMI = Association for the Advancement of Medical Instrumentation; DBP = diastolic blood pressure; ESH = European Society of Hypertension; rAIx = radial augmentation index; SBP = systolic 
blood pressure.



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Discussion
The NHS Long Term Plan pushes for a digital transformation where 

digitally enabled care will become mainstream.52 As the NHS shifts 

towards a digital-first approach for patient consultations, there must be 

robust and validated methods for remote patient monitoring to aid 

analysis and decision-making by clinicians. Concurrently, wearable 

technologies are increasingly ubiquitous, with an estimated 722 million 

devices connected to the internet.48,49 These trends are set to continue, 

with shipments of wearable devices expected to almost double from 

2019 to 2022, increasing from 226 million to 453.19 million.53 As these 

technologies become more widespread, clinicians have the 

responsibility to be early adopters, harnessing the potential they 

possess especially regarding their telemonitoring properties. However, 

before these technologies can be implemented clinically, a number of 

issues must first be addressed. 

Compliance and the Digital Divide
The digital divide is the difference between those who possess 

technological skills and those who do not.54 Cardiovascular diseases 

most commonly manifest in older patients, the cohort with the lowest 

rates of smartphone adoption and digital literacy.55 It has been 

suggested that older adults are reluctant to use mobile electronic 

devices due to factors such as lack of knowledge, disinterest or vision 

impairment.56 This potentially limits the use of wearable technology in 

this population.

Poor adherence has also been demonstrated in other groups. Several 

studies included in this review mentioned limitations of technology due 

to know-how or non-use. Ogink et al. found that only 36% of participants 

correctly performed BP measurements with their cuffless monitor after 

instruction.46 However, the authors suggested that education using a 

set procedure or an instructional video may increase correct 

usage.46,57,58 Nicolaï et al. found that 30% of patients in the wearable 

intervention group did not use the prescribed fitness tracker for the 

duration of the study or at all.33 Similarly, Endicott et al. reported 43% 

non-use of fitness trackers by participants.25 Although adherence to the 

use of fitness trackers was very good (>80%) in a series of trials by 

Gardner et al., it was noted that participants were volunteers.31,32 This 

exposes the study to selection bias, where patients who were more 

comfortable with technology or were more motivated were more likely 

to participate. 

Further work is needed to determine digital literacy in vascular patients. 

This could be achieved through validated literacy questionnaires such 

as eHEALS for eHealth literacy or MDPQ-16 for mobile device 

proficiency.59,60 Thus, appropriate wearable and telemonitoring 

interventions may be used and adequate coaching given to participants. 

Digital Infrastructure 
The expansion of wearable and telemonitoring interventions is limited 

by infrastructure. Hovey et al. investigated several practical aspects 

that negatively affected telemonitoring.61 Suboptimal internet 

connectivity, especially in rural areas, affected data collection and 

patient adherence. There were hardware issues that needed to be 

diagnosed remotely and required replacement equipment, thereby 

reducing patient access and increasing costs. Software issues were 

identified that could affect large-scale implementations of 

telemonitoring. For successful wearable and telemonitoring 

interventions, there is a need for robust and reliable infrastructure. 

Larger-scale extended studies could be conducted to validate the 

large-scale extension of a wearable or telemonitoring intervention.

Cost
The up-front cost of novel technology is often cited as prohibitive to 

widespread adoption. In fact, wearable and telemonitoring interventions 

may have cost benefits compared with conventional management. 

With regards to PAD management, a standard 3-month supervised 

exercise programme was estimated to cost about £235–£345 per 

patient in a 2013 study.62 In comparison, fitness trackers can cost as 

little as £21 per unit, although this can be considerably higher with 

more advanced devices. Furthermore, this cost can be offset by the 

reduction in travel expenses for the patient. These interventions 

additionally allow the individual tailoring of exercise requirements for 

each patient, which cannot be achieved with group supervised exercise. 

Similarly, telemonitoring hypertension interventions may be cost-

efficient. Low adherence to antihypertensive therapy was estimated to 

cost US$3,574 per patient over a 3-year period.49 In a 2015 study, 

Davidson et al. estimated the cost of their telemonitoring intervention 

(electronic medication tray, SMS encouragement, Bluetooth BP monitor 

and associated support staff) to be US$65 per month for patients who 

owned a smartphone and US$128 per month for those who did not.50 

Investigators noted that the average cost of an emergency department 

visit to be US$5,923 and the intervention group had a 57% reduction in 

visits compared with those receiving standard care, therefore giving a 

US$17,548 cost saving over a 6-month period. In addition, as 

telemonitoring can potentially identify patients with white-coat 

hypertension. It may avoid overtreatment and associated medication 

costs.7 There is a need, however, for further work to formally evaluate 

cost-effectiveness of wearable and telemonitoring interventions in 

cardiovascular patients. 

Conclusion
Wearable technologies are becoming increasingly prevalent and there 

is some evidence that wearable and telemonitoring interventions may 

be beneficial for managing vascular patients and keeping them out of 

hospital. With healthcare moving towards a digital future, it is inevitable 

that wearable devices and telemonitoring will become increasingly 

widespread in the clinical environment. More work is needed to validate 

these technologies with regards to digital literacy of patients, cost-

effectiveness and supporting digital infrastructure before widespread 

implementation. 

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