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      Digital interventions in the treatment of cardiovascular risk factors and atherosclerotic vascular disease

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          1 Introduction Cardiovascular disease and its complications such as myocardial infarction in particular, but also cerebrovascular disease with resulting stroke or peripheral arterial disease with acute limb ischemia or amputation are the leading causes of morbidity and mortality in the high-income countries world-wide [1]. In Europe, cardiovascular disease causes almost 4 million deaths per year, which accounts for almost 50% of all deaths [2]. Importantly, 30–40% of all patients who die from cardiovascular disease are younger than 75 years. Primary and secondary prevention aims at the efficient treatment of the modifiable risk factors, i.e. hypercholesteremia, diabetes mellitus, obesity and the fully established metabolic syndrome, arterial hypertension and smoking. Besides drug and interventional treatment, a healthy diet and an active lifestyle with at least modest regular exercise help reduce or even avoid cardiovascular complications. (See Table 1). Table 1 Studies with digital health interventions. First and last author Study acronym Number of participants (total/intervention vs control) Primary endpoints Successful (yes/no) Type of DHI doi Widmer&Lerman n/a 80/40 vs. 40 physical/biochemical metrics; behavorial characteristics yes online and smartphone https://doi.org/10.1016/j.ahj.2017.02.016 Anand&Beyene n/a 343/174 vs. 169 MI (myocardial infarction) risk score no emails and text messages https://doi.org/10.1001/jamacardio.2016.1035 Martin&Blaha mActive 48/16 vs. 32 change in steps/day yes text messages https://doi.org/10.1161/JAHA.115.002239 Glynn&Murphy SMART MOVE 90/41 vs. 37 change in steps/day yes smartphone app https://doi.org/10.3399/bjgp14X680461 Torbjørnsen&Ribu n/a 101/51 vs. 50 acceptability yes smartphone app https://doi.org/10.2196/mhealth.8824 Dallinga&Baart de la Faille-Deutekom n/a 3772/ 1976 vs. 1796 running physical activity yes smartphone app https://doi.org/10.1186/s12889-015–2165-8 Litman&Robinson n/a 726/464 vs. 262 physical activity (self-report) yes smartphone app https://doi.org/10.2196/jmir.4142 Turner-McGrievy&Tate n/a 85/48 vs. 37 activity levels; dietary intake; weight loss yes smartphone app https://doi.org/10.1136/amiajnl-2012–001510 Patel&Hilbert STEP UP 602/451 vs.151 change in steps/day yes wearable; gamification https://doi.org/10.1001/jamainternmed.2019.3505 Bennet&Miranda Track 351/176 vs. 175 weight change yes smartphone app; smart scale; telephone calls https://doi.org/10.1016/j.amepre.2018.07.005 Block&Block Alive-PD study 339/163 vs. 176 fasting glucose; HbA1c; body weight yes behavioural intervention via web app; internet; mobile phone; automated calls https://doi.org/10.2196/jmir.4897 Castro Sweet&Prewitt n/a 501 body weight; glucose/HbA1c; lipid profile; well being yes web/mobile information and tracking combined with human coaching https://doi.org/10.1177/0898264316688791 Alonso-Domínguez& Recio-Rodríguez EMID Study 204/102 vs. 102 adherence to Mediterranean diet yes smartphone app; workshop; exercise https://doi.org/10.3390/nu11010162 Frias&Osterberg n/a 109/80 vs. 29 change of systolic blood pressure yes Digital medicine offerings (digital medicine, wearable sensor patch and mobile device app) https://doi.org/10.2196/jmir.7833 Morawski&Choudhry MedISAFE-BP 411/209 vs. 202 medication adherence; change of systolic blood pressure yes Smartphone app (Medisafe app) https://doi.org/10.1001/jamainternmed.2018.0447 Johnston&Varenhorst SUPPORT study 174/91 vs. 83 medication adherence yes smartphone app https://doi.org/10.1016/j.ahj.2016.05.005 Zhang&Wang SBCHDP (smartphone-based coronary heart disease prevention) programme 80/40 vs. 40 perceived stress; behavioural risk factors no (but positive tendency) smartphone app (Care4Heart) https://doi.org/10.1186/s12955-017–0623-y Polizzi&Tolsma Quit Smart 97 (no control group, compared with published data) smoking cessation no audiotape (accompanied by discount vouchers for nicotine replacement therapy, group sessions and a self-help manual) https://doi.org/10.7812/tpp/03–048 Brendryen&Kraft Happy ending 290/ 144 vs. 146 abstinence from smoking yes internet and cell phone https://doi.org/10.2196/jmir.1005 Webb Hooper & Robinson n/a 140/ 70 vs. 70 feasibility and process variables, including intervention evaluations, readiness to quit yes DVD https://doi.org/10.1093/ntr/ntu079 Burford & Hendrie n/a 160/ 80 vs. 80 quit attempts at 6-month follow-up (self-reported and biochemically validated through testing for carbon monoxide (CO)) yes face aging software https://doi.org/10.2196/jmir.2337 Zeng & Bricker n/a 98 descriptive analysis of user characteristics and utilization of a app for smoking cessation – smartphone app https://doi.org/10.1089/tmj.2014.0232 Heffner & Bricker n/a 76 explorative analysis of most-used app features; prospective associations between feature usage and quitting – smartphone app https://doi.org/10.3109/00952990.2014.977486 Buller & Zimmerman n/a 102/ 51 vs. 51 self-reported usability of REQ-Mobile and quitting behavior no smartphone app; text messaging https://doi.org/10.1089/tmj.2013.0169 BinDhim & Trevena SSC App 684/ 342 vs. 342 smoking abstinence yes interactive smoking cessation decision-aid application https://doi.org/10.1136/bmjopen-2017–017105 Westmaas & Abroms n/a 1070/ 535 vs. 535 abstinence from smoking yes email https://doi.org/10.1136/tobaccocontrol-2016–053056 Lewis & Lyons n/a 35/ 19 intervention vs. 16 on waitlist (secondary mixed-method analysis) descriptive analysis of social support patterns using a mobile app for PA – Jawbone Up24 activity monitor and Apple iPad Mini; Social support features in the UP app included comments and likes https://doi.org/10.2196/12496 Tong & Laranjo n/a 55 (secondary mixed-methods feasibility study) descriptive analysis of users’ perspectives regarding mobile social networking interventions to promote physical activity – physical activity tracker and a wireless scale integrated with a social networking mobile app https://doi.org/10.2196/11439 Vandelanotte & Alley n/a 243/ 122 vs. 121 increase in physical activity yes 8 modules of theory-based, personally tailored physical activity advice and action planning. Participants were randomized to receive the same intervention either with or without Fitbit tracker integration. https://doi.org/10.2196/11321 Devi & Singh n/a 94/ 48 vs. 46 change in steps/day yes step count via accelerometer https://doi.org/10.2196/jmir.3340 Harris & Cook PACE-UPPACE-Lift PACE-UP: 236 (postal) vs. 231 (nurse support) vs. 214 (control)PACE-Lift: 108 vs. 117 (control) change in steps/day yes step count via pedometer +/- nurse counselling +/- postal counselling https://doi.org/10.1371/journal.pmed.1002526 Cardiovascular diseases and all modifiable cardiovascular risk factors are chronic conditions and hence demand permanent treatment and care. Furthermore, their incidence is growing in association with a demographically aging population [3]. Projected office visits will increase in the years to come [3]. But in contrast, contacts between patients and physicians are steadily decreasing due to restricted personnel and infrastructural resources, leaving only a few minutes for a single consultation of primary care physicians in most European countries [4]. Although the need drastically increases, the number of trained specialists may not rise adequately and hence aggravate the mismatch of medical experts and the ever-growing patient population [3]. Added to this is a lack of patients’ adherence, that, combined with the missing health care infrastructure, significantly restricts patient outcomes despite definitive medical guidelines and steadily improving treatment possibilities. Novel digital interventions and their associated strategies have been tested in a variety of diseases and feature a recently growing number of scientific studies and evidence (Fig. 1). Especially in the period between a widely received review and statement of the American Heart Association in 2015 [5] and now, numerous interventions with a focus on newly available technologies has been tested. Wearables and smartwatches in particular have been probably most recognizably used for the detection of heart arrythmia and are discussed to change the diagnostics of arrythmias sustainably [6], [7], [8], [9]. Studies like the Apple Heart Study promise a higher rate of accurate disease detection than possible under common circumstances, however the significance of these fine-spun diagnostic algorithms and their pathological relevance need to be addressed independently [10]. Image transmission for remote consultations accelerates medical care over long distances and basically ensures availability even in rural areas [11]. Through the wide spread of personal computers and mobile phones with internet connection within the industrialized countries, digital interventions experience their current success story. According to the Dutch market research company Newzoo, the top 5 countries with an estimated smartphone penetration of about 80% (i.e. percentage of the population that owns and uses a smartphone) are the United Kingdom, Netherlands, Sweden, Germany and the United States of America in 2018 [12]. Data by our own group show, that among German patients with peripheral artery disease the mobile phone usage is about 40–60% even in the older patient population of 60 years and above, although we found a decrease in usage with increasing age Fig. 1 Number of PubMed-listed publications per year for Mobile Health & cardiovascular, Digital Health Intervention & cardiovascular and Smartphone & cardiovascular. [13]. This still leaves approximately half of these patients sufficiently equipped for digital interventions at baseline, not considering patients who might acquire a device in order to optimize their treatment. Digital devices promise a much greater empowerment of patients independent of structural needs and may even improve compliance and adherence to medical treatment regimen and a recommended lifestyle. In this article, we will review the current approaches and possibilities of next generation patient care in the treatment of atherosclerotic disease and its modifiable risk factors. 2 Methods A selective scientific literature review from published peer-reviewed work was performed, using the search terms digital health hintervention (DHI), eHealth, mobile health (mHealth), smartphone, phone, messaging, web or internet in combination with cardiovascular disease, vascular disease, cardiovascular risk factors, physical activity, metabolic syndrome, hypertension, diabetes mellitus, lipids, cholesterol, weight loss, obesity, adherence, smoking or smoking cessation. Searches were performed in PubMed, Google Scholar, Science Direct and Scopus. Results were filtered for adequate matches by the authors for adequate matches. 2.1 Digital interventions and physical results Sufficient physical activity – i.e. at least 150 min of moderate exercise per week – has been identified as beneficial in many ways to promote health and has a central role in the secondary prevention for patients with cardiovascular disease [14]. On the contrary, a sedentary lifestyle is one of the leading risk factors for global mortality, but most adolescents and adults still do not meet the requirements of the current guidelines [15], [16]. Physical inactivity is on the rise not only in Europe or the USA, but affects general health globally in terms of cardiovascular and other non-communicable diseases [17]. Self-monitoring aims at the (at best permanent) modification of behavior [18]. One group performed a digital health intervention during cardiac rehabilitation after acute coronary syndrome. The intervention comprised an online website and a smartphone app, both with an exercise, dietary and weight diary including educational information during the course of a 12-week cardiac rehabilitation. After 90 and 180 days, patients with the digital intervention had a greater persisting weight loss (-5.1 vs −0.8 kg), but also less rehospitalization or visits in an emergency department [19]. A negative result despite a similar approach was in another study, who used text messages and emails to motivate patients to lower their estimated risk for a myocardial infarction. Subjects in both groups did not differ significantly at 12 months concerning their risk score or relevant outcome parameters like blood pressure, HbA1c, and waist-to-hip-ratios [20]. One possible explanation for the diverging results is a potential selection bias, due to the above-average motivation of all eligible participants and the high willingness to receive information about improving their activity and dietary lifestyle at baseline. Further, the mails and messages were addressed too impersonal in terms of the concerns of the study participants and also delivered at random intervals independent of the individual’s interest or need. In another trial, physical activity of subjects who attended a cardiovascular disease prevention program, was tracked with a specific smartphone app (Fitbug Orb). The participants received messages anytime they fall behind the aimed daily number of steps, what resulted in a significant increase in daily activity [21]. Finally, in a primary care setting, the simple use of an activity tracking app improved daily exercise [22]. Over the last years, several tools have been developed to support physical activity aiming for behavior change towards a more active lifestyle. Self-monitoring tools show both growth and a high user acceptance for the management of chronic diseases [23], [24], [25]. Through the fast advancements in the mobile phone sector, app-based mobile health (mHealth) technologies are perfectly suited to serve as a medium to deliver interventional strategies to support an improved health behavior. The increased availability of self-monitoring devices gave the opportunity to use these digital interventions as support for behavior change to implement a more active lifestyle on a large scale. Several studies focusing on self-monitoring using mHealth technologies are found to be associated with higher exercise levels, lower BMI, weight loss, and also healthier eating [26], [27], [28], but the overall effects seem to be modest over a longer period of time [29], [30], [31]. 2.2 Novel aids for overweight and metabolic syndrome Overweight and the metabolic syndrome are a global epidemic and closely related to cardiovascular morbidity [32]. Their treatment and prevention are essential aims in order to reduce cardiovascular disease, and also very suitable to be addressed by studies using innovative, digital strategies. The TRACK trial combined a coaching/counseling system with self-monitoring including mobile phone app and e.g. a wifi-connected scale in the weight loss program of 351 obese adults. The intervention group had and even sustained a greater weight loss after 6 and 12 months. Further, subjects in the intervention group with a higher commitment to the program yielded better results than those with less [33]. Overweight and diabetes are closely related to the metabolic syndrome, especially in the case of type 2 diabetes. In order to address a digital solution for diabetes prevention and weight loss, tailored, algorithm-based mail, phone and web interventions (so called “fully automated behavioral intervention systems, FABIS”) were tested in obese, in average 55 years old (pre-)diabetics [34]. The program used a weekly, personalized phone contact for the first 6 months, and a biweekly rhythm for the next 6 months, combined with midweek phone calls and email reminders. It was compared with standard care and a delayed start of intervention after 6 months. The patients with FABIS had significantly improved their glycemic control, body weight and lipid profiles after 6 months compared with the standard care control subjects [5]. Another study coalesced online tutorials, personalized human coaching and digital tracking tools in order to reduce the risk of diabetes in 501 participants with prediabetes and/or metabolic syndrome [35]. After a total of 12 months, the patients had lost 7.5% of their body weight and reduced their Hb1Ac for 0.14%. Unfortunately, the study lacked a proper control group, which weakens the significance of the findings, but still contributes to the ongoing debate. Motivational stimuli are essential for all self-dependent elements in medical interventions. For the individual subjects in a cohort, this may vary from sole self-improvement to head-on-head competition. The suitable type of those stimuli or even the combination of it are necessary to make the digital, self-controlled intervention work. A trial in healthy subjects of the Danish healthcare systems used a web-/mobile-app based tool and tested the benefits of a digital intervention in terms of weight lost, body fat and lipid profiles. Whereas the overall result revealed the difficulty of sustaining motivation to adhere to such tools, the in-detail analysis again showed (mild) improvements of waist circumference, body fat percentage and weight. The EMID study (Effectiveness of A Multifactorial Intervention in Increasing Adherence to the Mediterranean Diet) [36] investigated the adherence to the Mediterranean diet which has been proven to benefit or even prevent atherosclerotic disease [37], [38], [39], [40], [41]. In that randomized, controlled trial, all subjects received detailed counseling on the diet, and quality and amount of cardioprotective physical exercise. The intervention group (IG) additionally received a smartphone app for 3 months. After 3 months, IG had a better adherence to the Mediterranean diet. This effect was by trend persistent until the second follow-up after a total of 12 months. However, lipid or glycemic parameters did not significantly change [36]. 2.3 Adherence to therapeutic regimen The counseling for a healthier dietary regimen is one potential target for digital interventions, but to increase the adherence to medication and/or regular outpatient visits is another that deeply matters in the treatment of cardiovascular disease and its complications. A huge challenge to surveil medical adherence is the assessment of actual intake of pills in everyday routine. This issue has been elegantly addressed by Frias et al., who put sensor leaded placebos in the pill box of patients with hypertension and type 2 diabetes. The sensor, once ingested, provided a feedback signal to a wearable sensor patch and allowed an estimation of therapy compliance or inertia. The data were reviewed by patients, treating physicians and investigators and adapted if necessary. As a consequence, the patients featured a significantly improved blood pressure, lower LDL cholesterol and better HbA1c [42]. Nonadherence to medical treatment may account for half of the patients with uncontrolled arterial hypertension. One group used the Medisafe app, a smartphone app that works with reminder alerts, regular adherence reports and even peer support, and evaluated self-reported adherence and the impact on blood pressure. The Morisky Medication Adherence Scale showed a significant improvement in patients with the Medisafe app, however, both groups showed a decrease of systolic blood pressure of 10 mmHg after 12 weeks without significant difference between groups, pointing to a lack of extra value of the easy-to-use app system [43]. The SUPPORT study (A study to evaluate the use of mobile-phone based patient support in patients diagnosed with MI) used a web-based application to track drug adherence with an e-diary and also provide information after myocardial infarction. Whereas drug adherence was expectedly better in the app group, the authors also presented significantly higher effects for LDL lowering and patient satisfaction, but only numerical, non-significant differences in exercise or smoking cessation [44]. Another pillar of today's state-of-the-art treatment is the so called shared decision-making, which is based on partnership-based and equal decision-making by all relevant actors in the disease process [45]. Instead of simple data transmission, the implementation of shared decision-making elements additionally promotes knowledge about disease and treatment concepts and improves medication adherence, disease awareness, and self-management of chronic diseases. Through the process of shared decision-making, patients can take responsibility for their own health, which is called patient empowerment. The combination between digital interventions and the increase in patient empowerment might be promising. In the 4-week long Smartphone-Based Coronary Heart Disease Prevention (SBCHDP) program, subjects were either briefed and reminded by the Care4Heart app about coronary heart disease (CHD), or recommended website on CHD topics as control. Of note, most of the participants did not have established CHD, thus the primary outcomes were knowledge, perceived stress and behavioral risk factors. After the 4-week period, the intervention group with the Care4Heart app had significantly better CHD awareness and behavior as measured by lower cholesterol levels [46]. 2.4 Smart interventions for smoking cessation In 2004, a study was published, in which they had provided smokers with health instructions in group sessions, discount vouchers for nicotine replacement patches, education materials and interestingly audiotapes for hypnosis and relaxation [47]. This multimodal QuitSmart package was associated with significantly more smoking cessation than the standard care group. The authors found that nicotine patch and daily exercise majorly contribute to the success, but although the audiotape was an interesting, self-empowering component of it, it was omitted in the final analysis [47]. A first real digital cell (and not smart-, but rather dumb-) phone intervention study was published 2008 [48]. The Happy Ending (HE) program took 1 year and was delivered via Internet and cell phone, with some hundred contacts per subject in the course of the program. All components were already fully automated. During the trial period, patients with HE more frequently stopped smoking or were planning and preparing to do. However, the authors found that beyond 1 month (OR 3.46 for abstinence in HE group compared with control), a growing number of patients in both groups relapsed, the overall significant differences between HE and control persisted until 6 months (OR 2.59) and retained a clear trend until 12 months (OR 1.66, p = 0.07) [48]. Another media approach with a specifically, culturally-tailored DVD instead of a standard film yielded better quit rates in African-Americans at the follow-up after 1 month [49]. In Australia, an artificially changed photo was shown to half of the participants of another study, that simulated the aging process in a digital photo if or if not the person will quit smoking. All participants received advice for smoking cessation. The group with subjects who had seen their photoaging had a significantly higher rate of successful cessation when compared with standard care. Of note, in both groups half of the participants who indicated having stopped smoking were still tested positive with a CO breath analyzer, but that did not change the overall results [50]. Due to the wide acceptance and distribution of devices, a new generation of studies finally used smartphone apps to aid smoking cessation. Zeng et al. defined lower education, heavy smoking (greater than10 cigarettes per day for at least the past 30 days) and depression as relevant predictors for patients not to use a smartphone app [51]. The same group examined which parts of an app appeal to subjects and stated, that the users of their app SmartQuit mainly used features that are classically summarized as cognitive behavioral therapy (i.e. tracking, sharing, progress), with only 2 features (viewing a “quit plan” and practice of “letting urges pass”) being significantly associated with quitting [52]. Buller et al. tested a smartphone app vs. text messaging in a group of young (18–30 years old) smokers to achieve abstinence in 2014. The efficacy of text messaging for smoking cessation has been confirmed in a variety of studies before. Both interventions were finally used in about 60% of participants for 30 days, which was the end of the period of intervention. Whereas text messaging was slightly superior for the initial cessation – mainly due to the simple usage compared with the smartphone app- , the absolute abstinence until 12 weeks after start of the study lasted longer in the app group [53]. One of the biggest trials in the field with 684 participants tested a multi-functional app including information, motivational messages, diary and additional benefits vs an information-only version of the app. The subjects with a fully functional app showed a 1-month abstinence of 28.5% (vs 16.9%). However, the great effect at first steadily declined to a 6-months abstinence of 10.2% vs 4.8% in the control group [54]. These findings underline how important single, user-friendly elements of smartphone apps are to finally enable patient empowerment, but also how difficult persistence of non-smoking and adherence to the chosen therapeutic modality will be in real world settings. A highly patient-centered, very efficient approach was used in another study [55]. Patients received either a variety of tailored, i.e. personalized emails with information and motivation on how to quit smoking and persist a smoke-free life, few still tailored emails or general emails. Only patients with frequent, individual messages showed a significantly higher rate of smoking cessation, whereas both other groups fell behind in an equal measure, pointing out the relevance of individual, but also frequent and constant reminders. 2.5 Impact of web-based communities The implementation of behavior change theories in apps for physical activity is a relatively new phenomenon [56], [57]. Although, extended research in this field is still missing, so called social support has been identified as a major engagement tool and was shown to be associated to sustained behavior change [58], [59]. A common way to integrate social support into apps is via web-based social networking. This is mainly attached to setting up a personal profile, that can share personal activity and connect to other users, that includes functionalities like assessment through “likes” and comments of other users. Web-based solutions, in contrast to face-to face intervention, offers the benefits of time and cost savings, and include a wide reachability, immediate feedback from the peer group and if wanted also anonymity. Web-Based computer-tailored physical activity interventions were already shown to significantly increased intervention effectiveness [60], [61]. Nevertheless, it has been suggested that the support provided by web-based social networking platforms may mimic the support achieved through face-to- face interventions. Two major forms of web-based social networking platforms exist: the implementation into already existing platforms (e.g. Twitter or Facebook) and the direct implementation into commercial or researcher-derived health apps. Results regarding the effectiveness of social network interventions showed an increase in physical activity, but the generalizability is limited due to the heterogeneity of the analyzed studies [62], [63]. In summary, interventions implemented or delivered via web-based social networks were found to have the capacity to modify health-promoting behavior. This might result in a heightened effectiveness in their capacity to reach large audiences and sustain high levels of engagement. 2.6 Current barriers, gaps and future possibilities The efficacy of digital interventions is significantly influenced by the single person’s engagement with e.g. a specific app [64]. Major limiting factor is the adherence in terms of long-term engagement: only a minority use health and activity apps for more than 6 months, the vast majority rapidly loses interest and finally stops using the apps [65], [66]. This concerns not only healthy subjects who aim for a healthier lifestyle, but importantly also secondary prevention where mainly long-term behavioral changes towards a more active lifestyle are associated with health benefits [67], [68]. Strategies that improve user engagement linked to these technologies may include elements of gamification [29], [69] and devices deeply intertwined with everyday life like smartphones, wearables, or smart homes with fridges or entertainment systems [70]that deliver instant feedback of good or harmful behavior. The major limitations of scientific studies with digital health interventions are mainly a) the limited study time of mostly only a few weeks or months, b) endpoints with surrogate parameters or self-reports rather than major cardiovascular events like myocardial infarction or re-hospitalization, and finally c) the possibility of a selection bias, because only subjects with the necessary interest and also technical requirements if demanded were included in the majority of studies. Scientific studies on health psychology including health behavior models, behavioral change techniques, and motivational interviewing and coaching are not worked up systematically [71], [72], hence digital coaching which is based on these data is currently limited. Finally, a relevant impact on medical health care infrastructure and especially its relief from overload still need to be addressed. It will require almost complete independence from human resources like e.g. counselors, which may be possible with the latest, smartphone or web-based alone interventions. These limitations must not cloud the great possibilities of innovative digital interventions. From the studies in this review one may clearly deduce that well composed digital tools like apps with balanced general, but also personal, individual user interaction have a significant impact on primary and secondary prevention at least for a limited time. From our current point of view, digitization has already changed our healthcare system and patient care sustainably and will most likely become even more prominent in the near future. Declaration of Competing Interest The authors have nothing to declare.

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          Can Smartphone Apps Increase Physical Activity? Systematic Review and Meta-Analysis

          Background Smartphone apps are a promising tool for delivering accessible and appealing physical activity interventions. Given the large growth of research in this field, there are now enough studies using the “gold standard” of experimental design—the randomized controlled trial design—and employing objective measurements of physical activity, to support a meta-analysis of these scientifically rigorous studies. Objective This systematic review and meta-analysis aimed to determine the effectiveness of smartphone apps for increasing objectively measured physical activity in adults. Methods A total of 7 electronic databases (EMBASE, EmCare, MEDLINE, Scopus, Sport Discus, The Cochrane Library, and Web of Science) were searched from 2007 to January 2018. Following the Population, Intervention, Comparator, Outcome and Study Design format, studies were eligible if they were randomized controlled trials involving adults, used a smartphone app as the primary or sole component of the physical activity intervention, used a no- or minimal-intervention control condition, and measured objective physical activity either in the form of moderate-to-vigorous physical activity minutes or steps. Study quality was assessed using a 25-item tool based on the Consolidated Standards of Reporting Trials checklist. A meta-analysis of study effects was conducted using a random effects model approach. Sensitivity analyses were conducted to examine whether intervention effectiveness differed on the basis of intervention length, target behavior (physical activity alone vs physical activity in combination with other health behaviors), or target population (general adult population vs specific health populations). Results Following removal of duplicates, a total of 6170 studies were identified from the original database searches. Of these, 9 studies, involving a total of 1740 participants, met eligibility criteria. Of these, 6 studies could be included in a meta-analysis of the effects of physical activity apps on steps per day. In comparison with the control conditions, smartphone apps produced a nonsignificant (P=.19) increase in participants’ average steps per day, with a mean difference of 476.75 steps per day (95% CI −229.57 to 1183.07) between groups. Sensitivity analyses suggested that physical activity programs with a duration of less than 3 months were more effective than apps evaluated across more than 3 months (P=.01), and that physical activity apps that targeted physical activity in isolation were more effective than apps that targeted physical activity in combination with diet (P=.04). Physical activity app effectiveness did not appear to differ on the basis of target population. Conclusions This meta-analysis provides modest evidence supporting the effectiveness of smartphone apps to increase physical activity. To date, apps have been most effective in the short term (eg, up to 3 months). Future research is needed to understand the time course of intervention effects and to investigate strategies to sustain intervention effects over time.
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            Passive Detection of Atrial Fibrillation Using a Commercially Available Smartwatch

            Question How well can smartwatch sensor data analyzed by a deep neural network identify atrial fibrillation? Findings In this cohort study of 51 participants presenting for cardioversion, a commercially available smartwatch was able to detect atrial fibrillation with high accuracy. Among 1617 ambulatory individuals who wore a smartwatch, those with self-reported atrial fibrillation were correctly classified with moderate accuracy. Meaning These data support the proof of concept that a commercially available smartwatch coupled with a deep neural network classifier can passively detect atrial fibrillation. This study aims to develop and validate a deep neural network to detect atrial fibrillation using smartwatch data. Importance Atrial fibrillation (AF) affects 34 million people worldwide and is a leading cause of stroke. A readily accessible means to continuously monitor for AF could prevent large numbers of strokes and death. Objective To develop and validate a deep neural network to detect AF using smartwatch data. Design, Setting, and Participants In this multinational cardiovascular remote cohort study coordinated at the University of California, San Francisco, smartwatches were used to obtain heart rate and step count data for algorithm development. A total of 9750 participants enrolled in the Health eHeart Study and 51 patients undergoing cardioversion at the University of California, San Francisco, were enrolled between February 2016 and March 2017. A deep neural network was trained using a method called heuristic pretraining in which the network approximated representations of the R-R interval (ie, time between heartbeats) without manual labeling of training data. Validation was performed against the reference standard 12-lead electrocardiography (ECG) in a separate cohort of patients undergoing cardioversion. A second exploratory validation was performed using smartwatch data from ambulatory individuals against the reference standard of self-reported history of persistent AF. Data were analyzed from March 2017 to September 2017. Main Outcomes and Measures The sensitivity, specificity, and receiver operating characteristic C statistic for the algorithm to detect AF were generated based on the reference standard of 12-lead ECG–diagnosed AF. Results Of the 9750 participants enrolled in the remote cohort, including 347 participants with AF, 6143 (63.0%) were male, and the mean (SD) age was 42 (12) years. There were more than 139 million heart rate measurements on which the deep neural network was trained. The deep neural network exhibited a C statistic of 0.97 (95% CI, 0.94-1.00; P  < .001) to detect AF against the reference standard 12-lead ECG–diagnosed AF in the external validation cohort of 51 patients undergoing cardioversion; sensitivity was 98.0% and specificity was 90.2%. In an exploratory analysis relying on self-report of persistent AF in ambulatory participants, the C statistic was 0.72 (95% CI, 0.64-0.78); sensitivity was 67.7% and specificity was 67.6%. Conclusions and Relevance This proof-of-concept study found that smartwatch photoplethysmography coupled with a deep neural network can passively detect AF but with some loss of sensitivity and specificity against a criterion-standard ECG. Further studies will help identify the optimal role for smartwatch-guided rhythm assessment.
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              Cardiovascular risk and obesity

              Background This is an overview of the mechanisms of obesity and its relation to cardiovascular risks, describing the available treatment options to manage this condition. Main body The pathogenesis of obesity includes the balance between calories consumed and energy expenditure followed by the maintenance of body weight. Diet, physical activity, environmental, behavioral and physiological factors are part of the complex process of weight loss, since there are several hormones and peptides involved in regulation of appetite, eating behavior and energy expenditure. The cardiovascular complications associated to obesity are also driven by processes involving hormones and peptides and which include inflammation, insulin resistance, endothelial dysfunction, coronary calcification, activation of coagulation, renin angiotensin or the sympathetic nervous systems. Pharmacological treatments are often needed to insure weight loss and weight maintenance as adjuncts to diet and physical activity in people with obesity and overweight patients. Conclusion To accomplish satisfactory goals, patients and physicians seek for weight loss, weight maintenance and improvement of the risk factors associated to this condition, especially cardiovascular risk.
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                Author and article information

                Contributors
                Journal
                Int J Cardiol Heart Vasc
                Int J Cardiol Heart Vasc
                International Journal of Cardiology. Heart & Vasculature
                Elsevier
                2352-9067
                24 January 2020
                February 2020
                24 January 2020
                : 26
                : 100470
                Affiliations
                West German Heart and Vascular Center, Department of Cardiology and Angiology, University Hospital Essen, Germany
                Author notes
                [* ]Corresponding author at: University Duisburg-Essen, West German Heart and Vascular Center, Department of Cardiology and Angiology, Hufelandstrasse 55, 45147 Essen, Germany. martin.steinmetz@ 123456uk-essen.de
                Article
                S2352-9067(19)30237-4 100470
                10.1016/j.ijcha.2020.100470
                6994620
                f801d470-4471-41d7-b0d8-378f43796dfe
                © 2020 The Authors

                This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

                History
                : 20 October 2019
                : 1 January 2020
                : 12 January 2020
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