Efficacy of telemedicine on glycaemic control in patients with type 2 diabetes:A meta-analysis

Julia De Groot, Dongjun Wu, Declan Flynn, Dylan Robertson, Gary Grant, Jing Sun

Julia De Groot, Dongjun Wu, Declan Flynn, Dylan Robertson, School of Medicine, Griffith University, Gold Coast 4222, Queensland, Australia

Gary Grant, School of Pharmacy and Pharmacology, Griffith University, Gold Coast 4222,Queensland, Australia

Jing Sun, School of Medicine and Menzies Health Institute Queensland, Griffith University,Brisbane 4222, Queensland, Australia

Abstract BACKGROUND Telemedicine is defined as the delivery of health services via remote communication and technology. It is a convenient and cost-effective method of intervention, which has shown to be successful in improving glyceamic control for type 2 diabetes patients. The utility of a successful diabetes intervention is vital to reduce disease complications, hospital admissions and associated economic costs.AIM To evaluate the effects of telemedicine interventions on hemoglobin A1c (HbA1c),systolic blood pressure (SBP), diastolic blood pressure (DBP), body mass index(BMI), post-prandial glucose (PPG), fasting plasma glucose (FPG), weight,cholesterol, mental and physical quality of life (QoL) in patients with type 2 diabetes. The secondary aim of this study is to determine the effect of the following subgroups on HbA1c post-telemedicine intervention; telemedicine characteristics, patient characteristics and self-care outcomes.METHODS PubMed Central, Cochrane Library, Embase and Scopus databases were searched from inception until 18th of June 2020. The quality of the 43 included studies were assessed using the PEDro scale, and the random effects model was used to estimate outcomes and I2 for heterogeneity testing. The mean difference and standard deviation data were extracted for analysis.RESULTS We found a significant reduction in HbA1c [-0.486%; 95% confidence interval (CI)-0.561 to -0.410, P < 0.001], DBP (-0.875 mmHg; 95%CI -1.429 to -0.321, P < 0.01),PPG (-1.458 mmol/L; 95%CI -2.648 to -0.268, P < 0.01), FPG (-0.577 mmol/L;95%CI -0.710 to -0.443, P < 0.001), weight (-0.243 kg; 95%CI -0.442 to -0.045, P <0.05), BMI (-0.304; 95%CI -0.563 to -0.045, P < 0.05), mental QoL (2.210; 95%CI 0.053 to 4.367, P < 0.05) and physical QoL (-1.312; 95%CI 0.545 to 2.080, P < 0.001)for patients following telemedicine interventions in comparison to control groups.The results of the meta-analysis did not show any significant reductions in SBP and cholesterol in the telemedicine interventions compared to the control groups.The telemedicine characteristic subgroup analysis revealed that clinical treatment models of intervention, as well as those involving telemonitoring, and those provided via modes of videoconference or interactive telephone had the greatest effect on HbA1c reduction. In addition, interventions delivered at a less than weekly frequency, as well as those given for a duration of 6 mo, and those lead by allied health resulted in better HbA1c outcomes. Furthermore, interventions with a focus on biomedical parameters, as well as those with an engagement level >70% and those with a drop-out rate of 10%-19.9% showed greatest HbA1c reduction. The patient characteristics investigation reported that Hispanic patients with T2DM had a greater HbA1c reduction post telemedicine intervention. For self-care outcomes, telemedicine interventions that resulted in higher postintervention glucose monitoring and self-efficacy were shown to have better HbA1c reduction.CONCLUSION The findings indicate that telemedicine is effective for improving HbA1c and thus,glycemic control in patients with type 2 diabetes. In addition, telemedicine interventions were also found to significantly improved other health outcomes as well as QoL scores. The results of the subgroup analysis emphasized that interventions in the form of telemonitoring, via a clinical treatment model and with a focus on biomedical parameters, delivered at a less than weekly frequency and 6 mo duration would have the largest effect on HbA1c reduction. This is in addition to being led by allied health, through modes such as video conference and interactive telephone, with an intervention engagement level > 70% and a drop-out rate between 10%-19.9%. Due to the high heterogeneity of included studies and limitations, further studies with a larger sample size is needed to confirm our findings.

Key Words:Telehealth; Telemedicine; Telemonitoring; Behavioural change; Selfmanagement; Diabetes

INTRODUCTION

Type 2 diabetes mellitus (T2DM) is a chronic metabolic disorder in which the pancreas fails to secrete adequate insulin to maintain glucose homeostasis. Blood glucose levels are normally controlled by a series of anabolic and catabolic hormones, primarily insulin and glucagon, respectively[1]. It is evident that T2DM poses an extensive economic burden and negative consequences to health and healthcare systems. In 2014, an estimated 422 million people suffered from diabetes mellitus[2]. This equates to approximately 1 in 11 adults worldwide, 90% of whom suffer from T2DM[3]. The prevalence has nearly quadrupled since 1980 and current projections suggest that 642 million people will suffer from diabetes by 2040[2]. This is mainly attributed to rapid urbanisation, sedentary lifestyles and poor dietary habits[4]. In 2013, the Global Burden of Disease study found that diabetes was the 9thmost common cause for reduced life expectancy. Furthermore, 5 million deaths were attributed to diabetes in 2015,equating to 1 death every 6 s[5]. The estimated global economic burden of diabetes mellitus in 2015 was over 1.2 trillion USD[6].

A longitudinal cohort study that followed 117629 female nurses over 20 years found that participants with T2DM at baseline had a 5-times greater risk of myocardial infarction and cerebrovascular disease when compared to those without diabetes[7].Additionally, diabetes was the leading cause of blindness in individuals aged 20-74 years in 2011 and it was responsible for 44% of end-stage kidney disease and 60% of non-traumatic lower limb amputations[8]. Diabetes can also cause neuropathy through vascular disruption and direct neuronal injury. This may manifest as peripheral neuropathy affecting the extremities or autonomic neuropathy with organ dysfunction[9,10]. Some studies also suggest that T2DM is associated with a greater risk of depression, vascular dementia and Alzheimer’s disease[11,12].

Optimal diabetes management is necessary to slow disease progression, reduce complications and lessen the global healthcare burden[5]. Historically, weight loss and dietary changes have been the primary intervention to decrease visceral adiposity and improve glycaemic control[13,14]. Pharmacological management is also required where lifestyle modifications fail to achieve euglycemia[15]. Glycaemic control is closely monitored using glycosylated hemoglobin A1c (HbA1c) for long-term glycaemic control,vspost-prandial glucose (PPG) and fasting plasma glucose (FPG) for shortterm control[16]. Regular testing of the eyes, feet, blood pressure, lipids and urinary albumin excretion are also recommended to screen for possible complications[17].

Despite these interventions, 45% of patients with T2DM fail to achieve the target HbA1c[18]. One major barrier to adequate glycaemic control appears to be patient’s inability to perform adequate self-care, for example, poor adherence to prescribed medications and lifestyle modifications. A recent meta-analysis found that the adherence rate for anti-diabetic medications varied from 38% to 93%[18]. Qualitative studies suggest that poor adherence can be attributed to forgetfulness, medication side effects and insufficient patient education[19]. Self-care has been defined as the formation of knowledge and awareness needed to survive with the nature of a disease in both a health and social context[20,21]. Self-care behaviours relevant to T2DM that assist the disease management include nutrition, physical activity, blood glucose monitoring,medication adherence, disease knowledge, positive behaviour changes and selfefficacy[21]. Research has shown that self-care behaviours are vital to diabetes selfmanagement and have a direct impact on improving glycaemic control, quality of life(QoL) and decreasing incidence of complications[21,22]. Therefore, healthcare workers should aim to promote self-care behaviours in all T2DM interventions[21].

Other potential barriers to optimal glycaemic control in T2DM include inadequate patient outreach, time constraints and overly cautious prescribing habits[23,24]. These barriers have a profound effect on patient outcomes and healthcare costs. Studies have shown that the average patient cost is approximately 2.5-times higher in diabetes patients with a HbA1c greater than 10% compared to those with a HbA1c within the target range[25]. This is primarily due to a higher number of complications and hospitalisations in diabetics with poor glycaemic control[25]. Therefore, it is clear that effective interventions are required to improve patient outcomes and relieve the healthcare burden associated with T2DM.

In recent years, telehealth, also known as telemedicine, has been recognised as an effective way to deliver health services in rural and regional areas because it can be conducted remotely without compromising patient care[26]. Telehealth refers to the delivery of health services with the use of telecommunications and information technology[27]. It aims to maximise access to health services without any additional expense[28]. Telehealth is a broad term that can be classified as synchronous,asynchronous or remote monitoring. Synchronous telehealth refers to the delivery of health services in real time through smart devices,e.g., videoconferencing, mobile phone or computer. Asynchronous telehealth is when data relating to a patient is collected and reviewed at different points in time. Remote monitoring refers to the continuous evaluation of a patient’s clinical status based on specific health readings uploaded by the patient over the phone or online[29].

A review focusing on rural Australians found that telehealth provided better convenience, lower patient costs, improved access to specialist services and reduced hospital admissions[26]. These benefits also apply to patients with reduced mobility and other populations that experience a high degree of isolation[30,31]. Furthermore,telehealth has been shown to improve outcomes in psychiatric patients because it promotes greater self-efficacy and allows patients to maintain existing support networks[32,33]. Service providers also benefit from telehealth due to reduced travel expenses and greater educational opportunities for those working in remote areas[26].Numerous randomised control trials have been conducted to evaluate the effectiveness of telehealth in patients with T2DM. However, no studies have provided in-depth analysis of the effectiveness of telehealth on health improvement of patients with diabetes[34]. Therefore, this study aimed to utilise a meta-analysis approach to synthesise results from high quality randomised controlled trials, and to comprehensively review literature on the effects of telemedicine interventions on health outcomes for patients with T2DM. The secondary aim is to analyse the effect of telemedicine characteristics, patient characteristics, and self-care outcomes on glycaemic control post-intervention.

MATERIALS AND METHODS

Database search

The study protocol was registered on the International Prospective Register of Systematic Reviews (PROSPERO) prior to commencing the database search. Published randomised controlled trials (RCTs) that investigated the effect of telemedicine on T2DM were systematically searched on the following databases; Scopus, PubMed Central, Embase and Cochrane until June 18th2020. Additional records were identified on Proquest Central (Dissertations and Thesis). The search terms were:Type 2 diabetes* AND Telemedicine OR telehealth OR e-health OR eHealth OR m-health OR mHealth AND HbA1c OR glucose OR insulin OR HOMA OR homeostatic model assessment AND Randomised* OR Randomized* OR RCT.

Inclusion and exclusion criteria

Full-text studies written in English and published between January 1st1989 and June 18th2020 were included. The RCTs were required to report at least one primary outcome (HbA1c, insulin or HOMA-IR) and utilise telemedicine intervention in the intervention group(s) to be included. Classic telephone calls were not considered telemedicine. The participants were required to be minimum 18 years of age and have physician diagnosed T2DM or meet the minimum clinical measurements to be diagnosed in the study.

Studies were excluded if the control group contained any component of telemedicine intervention. Studies were excluded if they measured outcomes for less than 24 wk or the data was not separated from individuals with other forms of diabetes, such as Type 1 diabetes. Incomplete post-intervention data and conference abstracts were not included. If the same data set was used in multiple studies, the study with the completed data was included and the other(s) excluded.

Reasonable attempts were made to obtain full-text articles in the cases where it was not available online, including messages to authors on ResearchGate and email. The literature search was performed by De Groot J and Flynn D independently. Any discrepancies in narrowing and excluding studies were resolved in discussion with Robertson D and Sun J.

Selection of studies

Results of the searches were exported into EndNote software and duplicates were removed. Titles of the articles were screened to remove clearly irrelevant or non-RCT studies. Abstracts were read from the remaining list and further studies were excluded based on our criteria. For the remainder of studies, full text was reviewed for the purpose of data extraction, with some further exclusion of papers.

Quality assessment

PEDRO quality assessment was performed for all studies assessed for full text. Studies were excluded if they were scored ≤ 3 out of 10. A conservative approach was utilised,where if a component could not be confirmed, it was rated 0 for that component. The 10 components were randomisation, concealed allocation, group characteristics similar at baseline, subjects blinded, therapists blinded, assessors blinded, key outcome obtained from 85% of participants, intention to treat analysis, between group statistical analysis, and point measures with measures of variability.

Data extraction

Data extraction was completed by Flynn D and Robertson D, whilst De Groot J and Sun J verified all data entries with the full text of the published papers. The following information was collected from each paper; Table 1 study details, information for the PEDRO quality assessment and the primary and secondary outcomes at both pre- and post-intervention. Primary outcomes were HbA1c, HOMA-IR and insulin. Secondary outcomes were FPG, PPG, body mass index (BMI), weight, waist circumference,systolic blood pressure (SBP), diastolic blood pressure (DBP), total cholesterol (TC),depression, anxiety, QoL. The data was converted to mean and standard deviation where possible and appropriate. Data was converted from median and range if it was considered to have a normal distribution. The data set was excluded if it was not reported as mean ± SD and it was not appropriate to convert, for example a nonnormal distribution. Blood glucose was converted from mg/dL to mmol/L and blood lipids were converted from mg/dL to mmol/L. The short form (SF) health survey is used to measure QoL. Although the survey length can vary, each score is standardised from 0-100, 0 being maximum disability and 100 being no disability. The diabetes treatment satisfaction questionnaire was also included with the same standardisation[35]. Mean difference standard deviation was calculated if not provided by the study using the following equation:σ = sqrt (σ12/n1+ σ22/n2). Subgroup information was collected about patient demographics, characteristics about the telemedicine intervention and self-care outcomes.

Subgroups

Descriptive words about the intervention, patient demographic and self-care outcomes were collected from each paper. These were then manually coded into subgroups, as defined in the Supplementary Tables 1-4.

Mode of telemedicine intervention subgroups included Text message, Mobile Application, Interactive Telephone System, Online Server, Website, Videoconference,or Tablet/device. Duration of intervention subgroups included < 6 mo, 6 mo, > 6 mo <12 mo, or > 12 mo. Focus of intervention subgroups included biomedical parameters,self-management behaviours, or combination of biomedical parameters/selfmanagement behaviours. Model of intervention subgroups included behaviour change, clinical treatment, or behaviour change/treatment combination. Type of telemedicine intervention subgroups included telemonitoring, tele-education, or telemonitoring/tele-education combination. Intervention-lead subgroups included doctor, nurse, multi-disciplinary team, or allied health. Drop-out rate subgroups included 0%-9.9%, 10%-19.9%, or > 20%. Frequency of intervention subgroups included daily, < daily > weekly, weekly, or < weekly. Intervention engagement subgroups included < 70% or > 70%.

The self-care components considered for subgroups were related to:medication adherence, disease knowledge, behaviour change, self-glucose monitoring, hospital visits, self-efficacy, nutrition/diet, and exercise. These were categorised into subgroups based on whether there the telemedicine intervention improved significantly more than the control group in each self-care component. Regarding patient characteristic subgroups; racial group subgroups included Hispanic or Chinese, and comorbid disease subgroups included overweight/obese (BMI ≤ 25) and physician-diagnosed hypertension.

Statistical analysis

The random effects model was used to estimate effect sizes and mean differences in all outcomes andI2for heterogeneity testing. Publication bias was analysed using Egger regression analysis thatPvalue is more than 0.05 suggesting the publication bias is not significant. Sensitivity analysis was conducted by using removing one study per time and cumulative all studies to identify the results are related to particular study or studies.

Table 1 The characteristics of included studies (require insert reference for each study)

et al[44] 2015 compatible with glucometer, data transmitted to computers of Department of Endocrinology HbA1c for intervention vs control and T2D data.Recruitment ‘n’not provided Holmen et al[45] 2014 2, European Union +6 others(1) 51/50, (2)50/50 NB, Norway 58.6 (11.8)/55.9 (12.2)(1) 64/37,(2) 55/45(1) mobile phone based selfmanagement system app(automatic blood glucose transmission, input of diet and exercise info, goal managing). (2)Intervention 1 + telephone behaviour-change counselling from nurse for first 4 mo (12 mo)Usual care HbA1c, weight No significant differences 5 3 arm (2 interventions)Jeong et al[46]2018 4, Ministry of Health and Welfare,Republic of Korea and Ministry of Trade, Industry, and Energy South Korea(1) 113/113,(2)112/113 NB, South Korea 53.65 (9.10)/53.16(9.06)(1) 64/37,(2) 55/45(1) telemonitoring:outpatient clinic + tablet unit with auto blood glucose and weight transmission, diet and exercise monitoring with automated feedback texts. (2) telemedicine:intervention 1 + videoconference outpatient clinic (24 wk)Usual care HbA1c, FPG,PPG, BMI,body weight,SBP, DBP,HDL, LDL, TG Greater decrease in FPG for (1)telemonitoring group and (2) telemedicine group vs control 6 3 arm (2 interventions)a Kempf et al[47]2017 Multicentre,Boehringer Ingelheim International and University Dusseldorf 102/100 SB, Germany 59 (9)/60 (8)90/77 Glucometer, weight and pedometer data auto uploaded to online portal + weekly phone calls about lifestyle change and self-management (12 wk, 52 wk follow-up data)Usual care with selfmanagement guide, scale and step counter HbA1c, FPG,weight, BMI,SBP, DBP, TC,HDL, LDL,QoL Greater decease in HbA1c, body weight,BMI, SBP and QoL for intervention vs control 8 TG excluded as median (IQR)and skewed Kim et al[48]2007 1, College of Nursing Catholic University of Korea 30/30 NB, Korea 46.8 (8.8)/47.5 (9.1)22/29 Self-monitored glucose and medication use was submitted online and weekly recommendations were sent via text (6 mo)Usual care HbA1c, FPG,PPG Greater decrease in PPG for intervention vs control 5-Kim et al[49]2008 1, Korean Government 20/20 NB, Korea 45.5 (9.1)/48.5 (8)16/18 Medications and self-monitored glucose readings were used to create online medical record +weekly recommendations sent via text message (12 mo)Usual care HbA1c, FPG,PPG Greater decrease in HbA1c for intervention vs control 5-Kim et al[50]2016 1, UB care 110/110 NB, China 52.5 (9.1)/55.6 (10)88/94 Internet-based self-monitoring of blood glucose +recommendations via a website (6 mo)Usual care HbA1c, SBP,DBP, TC, TG,HDL, LDL Greater decrease in HbA1c and FPG for intervention vs control 4-Kim et al[51]2019 3, HealthConnect Co.97/94 NB, South Korea 60 (8.4)/56.7 (9.1)99/73 Smartphone modules for Bluetooth glucometer, diet,exercise via activity tracker +clinical decision support (24 wk)Usual care +Manual glucose logbook HbA1c, FPG,weight, SBP,DBP, TC, TG,LDL, HDL Greater decrease in HbA1c for intervention vs control 5 a Kleinman et al[52] 2017 3, Gather Health LLC 44/46 NB, India 48.8 (9)/48 (9.5)63/27 Mobile app provided daily reminders for self-management tasks and data + provider Usual care HbA1c, FPG,BMI Greater decrease in HbA1c, greater increase self-reported 7

communication and treatment adjustment (6 mo)medication adherence and BG testing for intervention vs control Lee et al[53]2020 11, Ministery of Science, Technology and Innovation Malaysia 120/120 SB, Malaysia 56.1 (9.2)/56.3 (8.6)108/132 Auto transmission of glucometer data via online portal with automatic feedback + team encouraged self-management monthly + change to medication if required (12 mo)Usual care HbA1c, FPG,SBP, DBP, TC,TG, HDL, LDL,QoL Greater decrease in HbA1c for intervention vs control 7 a Lim et al[54]2016 1, Korea healthcare technology R&D project 50/50 NB, Korea 64.3 (5.2)/65.8 (4.7)75/25 Bluetooth glucometer and activity monitor, and dietary and exercise transmission to website+ tailored feedback to device or mobile (6 mo)Usual care +self monitored blood glucose HbA1c, BMI,SBP, DBP, TC,TG, LDL, HDL,WC, FPG, PPG Greater decrease in HbA1c for intervention vs control 5-Liou et al[55]2014 6, none stated 54/41 NB, Taiwan 56.6 (7.7)/57 (7.5)48/47 6 sessions about diet, medication,stress management, goal setting and foot care, including 2 via teleconference (6 mo)Usual care + 1 in-person education session by nurse HbA1c, BMI,SBP, DBP, TC,TG, LDL, HDL Greater decrease in HbA1c for intervention vs control 5 TG excluded as log-transformeda Luley et al[56]2011 1, none stated 35/35 NB, Germany 59 (9)/58 (7)34/36 Bluetooth transmission from scales and accelerometer via Homebox to server + weekly feedback and progress via letters+ low calorie diet (6 mo)Usual care +conventional low fat diet Weight, BMI,HBA1c, TG,HDL, FPG Greater decrease in HbA1c weight, BMI and FPG for intervention vs control 5 a Nicolucci et al[57] 2015 Multi-centre, MSD Italia grant 153/149 NB, Italy 59.1(10.3)/57.8(8.9)94/92 Bluetooth transmission weight,blood glucose and blood pressure measurements to server via internet + remote support and GP feedback Usual care HbA1c,weight, SBP,DBP, TC, HDL,LDL, TG, QoL Greater decrease of HbA1c and increase of mental summary QoL for intervention vs control 4-Or et al[58]2020 1, Food and Health Bureau 151/148 NB, Hong Kong 63.9 (10.2)/63.7 (9.6)192/107 Bluetooth glucometer and BP monior + website-based technological surrogate nursing care encouraged selfmanagement via tablet with resources (24 wk)Usual care HbA1c, SBP,DBP No significant differences 7-Orsama et al[59] 2013 1, Finnish funding agency, Technical Research centre Finland & Bayer HealthCare 27/29 NB, Finland 62.3 (6.5)/61.5 (9.1)26/22 Mobile app transmission of weight, blood glucose, stepcount and blood pressure + automatic feedback with behaviour change focus + website viewing of health record Usual care HbA1c,weight, SBP,DBP Greater decrease in HbA1c and weight for intervention vs control 5 Baseline HbA1c up to 2 months were used Pacaud et al[60] 2012 1, Lawson Foundation(1) 18/21, (2)29/21 NB, Canada 52.1 (8.8)/56.3 (8.1)(1) 10/8,(2) 12/17(1) Webstatic:email consults (12 mo). 1A-male, 1B-female. (2) Web Interactive:online chat and email consults. 2A-male, 2B-female. (12 Usual care +education (faceto-face education,HbA1c, QoL No significant differences 5 5 arm (2 interventions and separation by sex). Post-test 'n

mo)group sessions)'not givena Pressman et al[61] 2014 Multi-centre,Samsung 118/107 SB, America 54.8 (9.8)/56.4 (8.7)122/76 Weekly transmission of blood glucose, blood pressure and weight to case manager via device + tailored telephone feedback (6 mo)Usual care Weight, BMI,SBP, LDL,HbA1c No significant differences 6 a Quinn et al[62]2016 Multi-centre,University of Maryland and WellDoc(1) 37/29, (2)25/27 NB, United States 47.3 (6.8)/47.4 (7.5)(1) 32/34,(2) 27/25 Mobile phone coaching App,entering blood glucose, diet,medication info with behavioural, motivation or feedback messages + Web portal(12 mo)Usual care HbA1c Greater decease in HbA1c for intervention vs control, no statistical difference for age groups 4 3 arm (separated by age < 55 and >55)Ramadas et al[63] 2018 3, Monash University 66/62 NB, Malaysia 49.6 (10.7)/51.5 (10.3)77/51 Web-based nutrition lesson plan and dietary intervention (12 mo)Usual care FBG, HbA1c No significant differences 7 Mean difference provided by study for HbA1ca Rodríguez-Idígoras et al[64] 2009 Multi-centre, Roche Diagnostics Spain 161/167 NB, Spain 63.32 (11.13)/64.52(10.32)169/159 Transmission of glucometer data via mobile + mobile contact by patient or healthcare staff when required + teleconsults (12 mo)Usual care HbA1c Greater decrease in HbA1c for intervention vs control 7-Shea et al[65]2009 2, Medicare and Medicaid + 6 more 844/821 SB, United States 70.8 (6.5)/ 70.9 (6.8)616/1049 Home unit with web-enabled computer access to website with education + webcam for videoconferencing + auto uploading glucometer and blood pressure data (5 yr)Usual care HbA1c, LDL,SBP, DBP Greater decrease in HbA1c (years 4-5)and LDL (years 1-4)and SBP (years 1-5)and DBP (years 1-5)for intervention vs control 5 Changed from Weinstock 2011,Adjusted mean used Stone et al[66]2010 Multi-centre, U.S.Air Force 64/73 SB, United States 3 × (< 45), 38 × (45-65), 23 × (> 65)/4 × (<45), 43 × (45-65), 26 ×(> 65)135/2 Transmission of blood glucose,blood pressure and weight via internet-connected device +monthly phone calls:selfmanagement education,medication changes (6 mo)Monthly phone call HbA1c,weight, SBP,DBP, TC, HDL,LDL, TG Greater decrease in HbA1c for intervention vs control 7-Sun et al[67]2019 1, Science Technology Department Jilin and Jilin University 44/47 NB, China 67.9 (66,71), 68.04 (66,72) Median (IQR)37/54 Mobile phone application +Bluetooth glucometer + advice every 2 wk via app (6 mo)Usual care +glucometer +outpatient visits HbA1c, PPG,FPG, TC, TG,BMI, SBP Greater decrease in HbA1c and PPG for intervention vs control 5 HDL, LDL, BMI,DBP excluded due to median(IQR) and skewed Tang et al[68]2013 1, Agency for Health Research and Quality 193/189 SB, United States 54 (10.7)/53.5 (10.2)249/166 Bluetooth glucometer readings +uploaded nutrition, exercise logs,insulin record online + messages with healthcare team and personalised text and video Usual care HbA1c, LDL,weight, SBP,DBP No significant differences at 12 mo,but greater decrease in HbA1c at 6 months of intervention vs control 7-Vinitha et al[69] 2019 5, AstraZeneca Pharma India Ltd 126/122 NB, India 42.4 (8.5)/44.1 (8.9)168/80 Text messages 3 times weekly:education, lifestyle, medication Usual care HbA1c,weight, BMI,Greater decrease in HbA1c, SBP and FPG 6 TG excluded due to median (IQR)

(24 mo)WC, SBP, DBP,FPG, PPG, TC,HDL, LDL,QoL for intervention vs control and skewed Wang et al[70]2017 1, Science Technology Department Jilin 106/106 NB, China 52.6 (9.1)/54.7 (10.3)116/104 Transfer of glucometer data to health centre via website +receival of information/advice (6 mo)Usual care HbA1c, TC,HDL, LDL Greater decrease in HbA1c, PPG, FPG and TG for intervention vs control 4 FPG, TG, BMI,SBP, DBP, PPG excluded due to median (IQR)and skewed Wang et al[71]2018 1, National Center for Clinical and Translational Sciences grant 11/6 NB, United States 58.8 (5.9)/49.2 (10.2)7/10 Smartphone application +Bluetooth scale and glucometer +12 in-person behaviour-change sessions (6 mo)Usual care HbA1c Greater decrease in HbA1c for intervention vs control 5 Paper group intervention not included here Wayne et al[72]2015 2, Public Health Agency Canada 67/64 NB, Canada 53.1 (10.9)/53.3 (11.9)28/72 Mobile phone monitoring and health coaching (6 mo)Health coaching without mobile HbA1c,weight, WC,BMI,depression,anxiety, QoL Greater decrease in BMI and greater increase in QoL(Mental SF-12) for intervention vs control 5-Welch et al[73]2011 1, Baystate Medical Center 25/21 NB, United States 54.4 (10.4)/57.5 (9.5)31/15 Transmission of comprehensive patient data to clinician via internet + 7 in-person visits of 1 h diabetes education (12 mo)7 in-person visits of 1 h diabetes education HbA1c, SBP,DBP, BMI Greater decrease in HbA1c and SBP for intervention vs control 4 Depression excluded due to nil measure of variance Whittemore et al[74] 2020 5, none stated 26/21 SB, Mexico 53.9 (9.2)/56.8 (8.3)16/31 7 weekly self-management group sessions + 6 mo daily text messages about behaviour change + unconnected glucometer (6 mo)Usual care(waitlist for intervention)HbA1c, SBP,DBP BMI,depression No significant differences 7 a Wild et al[75]2016 4, Chief Scientist Office Grant 160/161 SB, United Kingdom 60.5 (9.8)/61.4 (9.8)214/107 Bluetooth transmission of glucose, blood pressure and weight to website + called when lifestyle and medication changes required (9 mo)Usual care HbA1c, SBP,DBP, weight Greater decrease in HbA1c, SBP and DBP for intervention vs control 7-Williams et al[76] 2012 3, QLD Health, HCF Health and Medical Research Foundation 60/60 NB, Australia 58.4 (8.2)/56.4 (8.3)76/44 Bluetooth Glucometer +Interactive automated telephone system encouraging selfmanagement behaviours (6 mo)Usual care HbA1c, QoL Greater decrease in HbA1c and improved mental HRQL for intervention vs control 5-Xu et al[77]2020 1, National Institutes of Health, Veterans Affairs 33/32 NB, United States 54.6 (1.82)/55.34(1.94)20/44 Glucose data self reported and collected by automated phone calls/texts, shared with providers with bidirectional communication (12 mo)Usual care HbA1c No significant differences 5 Excluded FPG measures as it was patientreported Yip et al[78]2002 1, none stated 41/41 SB, China 55.29 (8.63)/57.54(8.52)70/52 4 educational sessions via videoconference + telephone Usual care HbA1c No significant differences 5 Additional nontelehealth group

aP < 0.05. SBP:Systolic blood pressure; DBP:Diastolic blood pressure; BMI:Body mass index; TC:Total cholesterol; MD:Mean difference; CI:Confidence interval; FPG:Fastening plasma glucose; WC:Waist circumference; PPG:Postprandial glucose; QoL:Quality of life.

RESULTS

Study selection

We identified 673 total potential studies from the database search, with 1322 additional records identified through other sources. After removing duplicates, 1731 studies remained to be screened by title and abstract. Full-text screening was conducted on the remaining 59 studies, 16 of which were excluded as a result of the study design or data insufficiency. Due to multiple arm trial designs, the final sample for meta-analysis included 43 eligible studies in quantitative synthesis in total (Figure 1).

Study characteristics

The 43 included studies were published between 2002 and 2020, and reported 4365 participants receiving a telemedicine intervention and 4045 participants in the control groups. Participants were recruited from 16 countries including Saudi Arabia, United States, Poland, South Korea, Greece, Italy, Norway, Germany, India, Malaysia, China,Finland, Canada, Spain, Mexico, and Australia. Participants in the intervention group received telemedicine intervention while those in the control group did not. All included studies measured at least one of the required outcome variables, which was consistently HbA1c. The outcomes of SBP, DBP, PPG, FPG, BMI, cholesterol, weight,mental QoL, and physical QoL were also collected from the studies. The demographic characteristics of the participants, intervention and control details, measured outcomes, key results and PEDRO quality assessment of the included studies are summarised and presented in Table 1[36-78].

Primary outcomes and subgroup analysis

Figure 1 PRISMA flow chart of study selection.

Forty-three studies involving 6932 participants measured HbA1c changes in diabetes patients. The pooled effect on HbA1c was -0.486% [95% confidence interval (CI) -0.561 to -0.410,P< 0.001] in the telemedicine group compared with the usual care group,with a significantly high-level of heterogeneity (I2= 98.290%,P< 0.001). Our results found that all modes of telemedicine interventions had a significant HbA1c reduction (P< 0.001), six of them with significant heterogeneity (P< 0.001) including text message(-0.591%; 95%CI -0.892 to -0.290,P< 0.001), mobile application (-0.359%; 95%CI -0.502 to -0.215,P< 0.001), interactive telephone (-0.782%; 95%CI -1.172 to -0.391,P< 0.001),internet server/computer network (-0.431%; 95%CI -0.558 to -0.304,P< 0.001), website(-0.539%; 95%CI -0.706 to -0.371,P< 0.001), and device/tablet (-0.278%; 95%CI -0.747 to 0.191,P< 0.001); only videoconference interventions (-0.845%; 95%CI -1.144 to -0.546,P< 0.001) had no significant heterogeneity. A significant HbA1c reduction (P<0.001) with a significantly high-level of heterogeneity (P< 0.001) was found in all short-term and long-term trials. In addition, interventions of 6 mo duration were observed to have a greater HbA1c reduction (-0.626%; 95%CI -0.766 to -0.486,P<0.001) compared to trials less than 6 mo, or more than 6 mo. Our results reported that 16 studies had interventions focussed on biomedical parameters only (-0.687%; 95%CI-0.821 to -0.553,P< 0.001) and 24 studies had interventions focussed on both biomedical parameters and self-management behaviours (-0.348%; 95%CI -0.442 to -0.253,P< 0.001) which had a significant HbA1c reduction (P< 0.001) and high level heterogeneity (P< 0.001), compared to 7 studies which had interventions focussed on self-management behaviour only, with no significant HbA1c reduction.Telemonitoring significantly reduced HbA1c (-0.553%; 95%CI -0.662 to -0.445,P<0.001) and had greater HbA1c reduction compared to those trials using tele-education only (-0.495%; 95%CI -0.683 to -0.307,P< 0.001) and combined telemonitoring and teleeducation (-0.391%; 95%CI -0.542 to -0.240,P< 0.001). We also found that those trials with a behaviour change model of intervention (-0.452%; 95%CI -0.575 to -0.329,P<0.001) and clinical treatment model of intervention (-0.589%; 95%CI -0.725 to -0.453,P< 0.001) reported a significant HbA1c reduction and was associated with heterogeneity(P< 0.001). Six trials conducted a combined behaviour change and treatment model for intervention which also reported a significant HbA1c reduction (-0.401%; 95%CI -0.612 to -0.189,P< 0.001) with heterogeneity (P< 0.001). The telemedicine interventions lead by allied health (-0.939%; 95%CI -1.651 to -0.227,P< 0.01) reported a greater HbA1c reduction compared to those led by doctors (-0.288%; 95%CI -0.512 to -0.064,P< 0.05),nurse lead interventions (-0.491%; 95%CI -0.655 to -0.327,P< 0.001) and led by a multidisciplinary team (-0.534%; 95%CI -0.643 to -0.425,P< 0.001). Patients who received a weekly intervention (-0.791%; 95%CI -1.167 to -0.416,P< 0.001) and less than weekly (-0.835%; 95%CI -1.068 to -0.602,P< 0.001) reported a greater HbA1c reduction with high heterogeneity (P< 0.001) compared to those patients who received intervention greater than weekly but less than daily (-0.307%; 95%CI -0.462 to -0.152,P< 0.001) and daily interventions (-0.439%; 95%CI -0.577 to -0.302,P< 0.001). The telemedicine interventions with a drop-out rate of 10-19.9% (-0.645%; 95%CI -0.786 to -0.504,P<0.001) reported a greater HbA1c reduction compared to those with a drop-out rate of 0-9.9% (-0.458%; 95%CI -0.584 to -0.333,P< 0.001), or a drop-out rate 20%+ (-0.297%;95%CI -0.472 to -0.121,P< 0.001). The telemedicine interventions with an engagement level > 70% (-0.576%; 95%CI -0.696 to –0.455,P< 0.001) a greater HbA1c reduction whilst interventions with engagement levels < 70% did not significantly reduce HbA1c in the analysis.

The self-care outcomes analysis identified that studies with intervention participants with significantly higher self-glucose monitoring (-0.505%; 95%CI -0.923 to-0.087,P< 0.05) with high heterogeneity (P< 0.001), and significantly higher selfefficacy (-0.810%; 95%CI -1.013 to -0.607,P< 0.001) by the end of the intervention showed significant reductions in HbA1c. However, we found that studies where intervention participants had significantly different medication adherence, disease knowledge, hospital visits, nutrition, and behavior change had no effect on HbA1c.

The patient characteristic subgroup analysis revealed that Hispanic participants receiving telemedicine had significantly reduced HbA1c (-0.867%; 95%CI -1.052 to -0.682,P< 0.001), which was greater in comparison to the remainder of the studies (-0.464%; 95%CI -0.540 to -0.388,P< 0.001). Obese participants receiving telemedicine had high heterogeneity (P < 0.001) but significantly decreased HbA1c (-1.270%; 95%CI-1.971 to -0.568,P< 0.001), whilst the hypertensive patients also had decreased HbA1c(-0.100%; 95%CI -0.136 to -0.064,P< 0.001). However, the remainder of studies in comparison had a greater reduction in HbA1c (-0.439%; 95%CI -0.516 to -0.361,P<0.001), with high heterogeneity (P< 0.001) (Tables 2 and 3).

Secondary outcomes

Our results also found significant reductions in DBP (-0.875 mmHg; 95%CI -1.429 to -0.321,P< 0.01), PPG (-1.458 mmol/L; 95%CI -2.648 to -0.268,P< 0.01), FPG (-0.577 mmol/L; 95%CI -0.710 to -0.443,P< 0.001), weight (-0.243 kg; 95%CI -0.442 to -0.045,P< 0.05), BMI (-0.304; 95%CI -0.563 to -0.045,P< 0.05), but increase in Mental QoL(2.210; 95%CI 0.053 to 4.367,P< 0.05) and Physical QoL (1.312; 95%CI 0.545 to 2.080,P< 0.001) for the telemedicine intervention, compared to control. However, twenty-two studies involving 4053 participants were analysed and the pooled effect of SBP was not significant (P> 0.05) in the telemonitoring group compared to the control group.Moreover, 15 studies with 2951 participants reported no significant difference in cholesterol change in the intervention group compared to the control group (Figures 2 and 3).

Publication bias

The study by Sheaet al[65]for SBP and DBP was excluded from the analysis due to its significant publication bias. After removing this study, visual inspection of the funnel plots of SBP and DBP (Supplementary Figure 1) showed a symmetrical distribution of the effect size, and no obvious publication bias was found. Egger’s test (Table 2) of SBP(t= 0.937, 95%CI -2.814 to 7.432,P> 0.05), DBP (t= 0.896, 95%CI -5.695 to, 2.280,P>0.05), PPG (t= 0.035, 95%CI -9.234 to 8.984,P> 0.05), weight (t= 1.225, 95%CI -3.014 to 0.814,P> 0.05), mental QoL (t= 1.124, 95%CI -13.969 to 32.978,P> 0.05) and physical QoL (t= 0.425, 95%CI -8.626 to 12.046,P> 0.05) supported the funnel plot findings indicating that no publication bias was found in the comparison. However, egger’s test(Table 2) of HbA1c (t= 2.604, 95%CI -6.389 to -0.815,P< 0.05) FPG (t= 2.730, 95%CI -4.501 to -0.524,P< 0.05) and BMI (t= 2.963, 95%CI -4.376 to -0.701,P< 0.05) indicated significant publication bias in this comparison. Removing any study did not change the overall significant results, suggesting all included studies are contributing to the overall results.

DISCUSSION

This meta-analysis systematically reviewed 43 RCTs examining the effects oftelemedicine on HbA1c, blood pressure, PPG, FPG, weight, BMI, cholesterol, Mental QoL, and Physical QoL in patients with diabetes. Our research reported that telemedicine interventions have a significant effect on lowering HbA1c; -0.486%(95%CI -0.561 to -0.410,P< 0.001,I2= 98.290%) in comparison to the controls. The improvement of HbA1c control by telemedicine is consistent with previous research[2,79,80]. In addition, our results also report a significance reduction on DBP (P<0.01), PPG (P< 0.01), FPG (P< 0.001), weight (P< 0.05), BMI (P< 0.05), Mental QoL (P< 0.05), and Physical QoL (P< 0.001) in the intervention group. However, our results found no significant effect (P< 0.05) on SBP and cholesterol in the intervention group compared to the controls. Although there is significant heterogeneity found in all outcomes, the positive effect of telemedicine is promising. However, the clinical significance of these results must be considered. A 0.875 mmHg reduction in DBP is not very impactful, as normal DBP can range from 80 mmHg or lower[81]. But a PPG reduction of 1.458mmol/L is significant as the upper limit of normal is only 7.8mmol/L[82], which would be a more meaningful change.

Table 2 Result of all variable analysis of included studies in meta-analysis

Effect of telemedicine characteristics on glycaemic control

In this study, we evaluated the effect of telemedicine intervention characteristics on T2DM in terms of changes to HbA1c. The subgroup analysis showed that interventions provided at a frequency that is less than weekly (-0.835%; 95%CI -1.068 to -0.602,P< 0.001,I2= 86.760%) provided the greatest reduction in HbA1c. This is an interesting result, with the least frequent intervention revealing the highest glycaemic control. A possible reason for this could be that the participants with less frequent interactions may tend to work towards achieving goals in between each interaction,rather than with a daily or weekly intervention where motivating progress is less experience in each interaction. Patients that received an intervention duration of 6 mo(-0.626%; 95%CI -0.766 to -0.486,P< 0.001) also reported a higher HbA1c reduction. A previous study[83]reported similar results suggesting that 6 mo telemedicine intervention significantly improves HbA1c levels in patients with diabetes patients. In addition, the long-term telemedicine intervention (more than 6 mo) was also found significant for HbA1c improvement, which is consistent with another systematic review[84]. These findings suggested that telemedicine intervention may facilitate HbA1c control for 6 mo or longer.

Table 3 HbA1c subgroup analysis for included studies

Allied health, diabetes educator, dietician, councillor.aP < 0.05.bP < 0.01.cP < 0.001. CI:Confidence interval.

The impact of telemedicine on HbA1c may be also explained by the different modes of intervention, including text message, mobile app, interactive telephone, internet server, website, video conference and mobile devices[85]. Although all modes of intervention demonstrated significant HbA1c improvement, it is an opportunity to highlight that interactive telephone (-0.782%; 95%CI -1.172 to -0.391,P< 0.001) and videoconference (-0.845%; 95%CI -1.144 to -0.546,P< 0.001) showed a greater HbA1c reduction than other modes of interventions. A study reported similar results to this,theorising that interactive treatment may facilitate remote healthcare on diabetes management[84]. Our results suggest that all modes of intervention are significant for T2DM telemedicine, but perhaps we should pay more attention to the modes of interactive telephone and videoconferencing. However, due to the number of study limitation for videoconference and interactive phone call interventions, more relevant trials are needed for further confirmation.

In the studies we reviewed, telemonitoring interventions, as well as combined telemonitoring and tele-education interventions significantly reduced HbA1c in T2DM patients. In addition, combined behaviour change and clinical treatment models, as well as either behaviour change or clinical treatment models intervention alone, had significantly improved HbA1c levels. Specifically, clinical treatment models of intervention resulted in the greatest decline in HbA1c. Several published studies evidence the positive effect of diabetes treatment by telemonitoring[83,86-88]and teleeducation[83,89]. This may be due to healthy behaviour changes[89-92]in addition to medical treatment[93]resulting in disease improvement during the course of telemedicine interventions.

Similarly, telemedicine interventions that focused on biomedical parameters were most effective at reducing HbA1c, followed by biomedical parameters in addition to self-management behaviour focus. The self-management focus alone did not significantly reduce HbA1c, suggesting that the interventions aimed to achieve specific numeric targets (such as HbA1c level, blood glucose level, kilograms of weight loss)are more effective to achieve glycaemic control.

We also found that telemedicine interventions led by allied health, multidisciplinary or nurse-led interventions showed a better HbA1c control compared to those led by doctors. Due to the characteristics of diabetes management, patients may require not only medications but also lifestyle guidance[79,90,91]. Interventions lead by nurse, allied health and multi-disciplinary teams may provide a better strategy for long-term diabetes treatment. Interestingly, interventions with drop-out rates between 10%-19.9% revealed the greatest reduction in HbA1c. This could be explained by the notion that interventions with lower drop-out rates might retain participants that can be less compliant to the intervention. This is supported by the result that telemedicine interventions with a higher engagement level (> 70%) have greater HbA1c reduction.

Effect of self-care components on HbA1c

Intervention participants that had significantly higher self-glucose monitoring and significantly higher self-efficacy at the end of the intervention showed significantly higher reductions in HbA1c. These results are consistent with a previous metaanalysis[94]. Furthermore, another meta-analysis highlighted that increased self-glucose monitoring results in a reduction of HbA1c and therefore long-term glycemic control[95]. Higher self-efficacy has also been shown to reduce HbA1c[96]. T2DM patients with better self-care knowledge and perform more self-care behaviors will manage their disease more frequently, improving glycemic control and reducing complications[96]. Thus, it would be beneficial to incorporate self-care education and encouragement in the provision of telemedicine interventions for T2DM.

However, most of the trials did not mention the self-care components of nutrition,behaviour change, hospital visits, disease knowledge and medication adherence. Thus,our result on self-care outcomes should be interpreted cautiously. More research of higher methodological quality and larger number of studies are needed to explore whether telemedicine intervention can facilitate self-care development[94].

Figure 2 Effects of telehealth intervention on hemoglobin A1c, systolic blood pressure, diastolic blood pressure, post-prandial glucose,fasting plasma glucose, and weight effect size plot.

Effect of patient characteristics on HbA1c

It is well known that both obesity and T2DM are metabolic diseases that are contributed by an unhealthy lifestyle[97]. In the studies we reviewed, 318 participants were diagnosed with both T2DM and a BMI considered overweight/obese (BMI > 25),which reported a significant HbA1c reduction after telemedicine intervention. There was a similar result for the hypertensive T2DM patients, however there was only 1 study with 299 participants reporting this. There are difficulties determining the number of participants with a BMI > 25 or hypertension in the studies that did not explicitly calculate this. Furthermore, due to the sample size limitation and high heterogeneity, the effectiveness of telemedicine interventions for T2DM and comorbid diseases should be interpreted with caution. Two studies had Hispanic only patients,reporting a total of 318 participants whom had a greater reduction in HbA1c after telemedicine intervention, in comparison to the remainder of studies. Although, the same issue of high heterogeneity and small sample size persists.

Limitations

This meta-analysis covered various telemedicine interventions for patients with T2DM. We aimed to perform a comprehensive meta-analysis on the effect of telemedicine intervention in the treatment of T2DM. However, our research has some limitations that must be acknowledged. First, we found high heterogeneity for all outcomes and most of the subgroups. The heterogeneity may be caused by the complexity of telemedicine interventions such as duration, strategies, combinations and telemedicine quality. Second, we found that the effectiveness of self-care outcomes is uncertain due to the study number limitations. More trials with large sample sizes and details on self-care outcomes are needed for further investigation. Lastly, although telemedicine interventions showed a significant improvement in mental and physical QoL, the sample size limitation may cause uncertainty and high heterogeneity. Thus,more trials with large sample sizes are needed for further telemedicine evaluation on mental and physical QoL. Considering these limitations, the results of this metaanalysis should be interpreted with caution.

CONCLUSION

Figure 3 Effects of telehealth intervention on body mass index, cholesterol, mental health and physical health effect size plot.

Our findings demonstrated that telemedicine interventions are more effective than the controls for reducing HbA1c in T2DM patients. In addition, the outcomes of DBP,PPG, FPG, weight, BMI, mental QoL and physical QoL improved significantly more in telemedicine interventions when comparing to control. SBP and cholesterol were not significantly different when compared to control. In addition, several components of telehealth characteristics were found to have an effect on glycaemic control through subgroup analysis. The studies that emphasized both behaviour change and treatment models of intervention, as well as interventions deliveredviamodes such as videoconference and interactive telephone had a larger effect on HbA1c reduction. In addition, less than weekly intervention frequency and intervention durations of 6 mo or longer may obtain a better outcome for glucose control. Interventions focused on biomedical parameters, as well as the method of telemonitoring, and those lead by allied health had a better effect on glucose control. Furthermore, interventions with a drop-out rate between 10%-19.9% and engagement levels of > 70% had the greatest HbA1c reduction.

The patient characteristic investigation reported patients with T2DM that were overweight, as well as Hispanic participants showed a greater HbA1c reduction. The current results also suggest that telehealth interventions that improve glucose monitoring and self-efficacy by the end of the study may be important for self-care development and can result in significant HbA1c reduction. Due to the trial limitation,components including nutrition, exercise, behaviour change, medication adherence,and disease knowledge in telehealth interventions have an uncertain effect on HbA1c.Ultimately, due to the characteristics of telehealth interventions and their positive effect of on diabetes management, we recommend the provision of telehealth interventions with emphasis on patient self-care for better management of T2DM,which may enhance long-term glucose control for patients. In addition, future studies should record more details about telehealth methodology and outcomes, especially self-care, for further evaluation.

ARTICLE HIGHLIGHTS

Research background

Telemedicine is defined as the delivery of health services via remote communication and technology. It is a convenient and cost-effective method of intervention, which has shown to be successful in improving glyceamic control for type 2 diabetes patients.The utility of a successful diabetes intervention is vital to reduce disease complications, hospital admissions and associated economic costs.

Research motivation

There are numerous randomised control trials that evaluate the effectiveness of telemedicine in patients with diabetes. However, no studies have provided an indepth analysis of the effectiveness of telemedicine for glycaemic control and other health outcomes for type 2 diabetes patients.

Research objectives

This study aimed to utilise a meta-analysis approach to synthesise results from high quality randomised controlled trials, and to comprehensively review literature on the effects of telemedicine interventions on health outcomes for patients with type 2 diabetes. The secondary aim was to analyse the effect of telemedicine characteristics,patient characteristics, and self-care outcomes on glycaemic control.

Research methods

Fourty-three relevant studies were yielded from PubMed Central, Cochrane Library,Embase and Scopus databases which satisfied quality assessmentviathe PEDro scale.Mean difference and standard deviation was extracted from pre- and post-intervention data regarding all outcomes of interest, and information for subgroup categories was collected. The random effects model was used to estimate outcomes andI2was used for heterogeneity testing.

Research results

Telemedicine improves hemoglobin A1c (HbA1c), diastolic blood pressure, postprandial glucose, fasting plasma glucose, weight, body mass index, mental quality of life and physical quality of life score significantly more than control/non-telemedicine interventions.

Subgroup analysis revealed that telemedicine interventions that involved primarily telemonitoring, used a clinical treatment model, deliveredviamodes such as videoconferencing and interactive telephone, at a rate less frequent than weekly,provided for a duration of 6 mo, led by allied health workers, focussed on biomedical outcomes, had high engagement level and moderate drop out rate were the most effective at reducing HbA1c.

Subgroup analysis about patient characteristics showed that Hispanic patents may benefit more than others in HbA1c reduction. Self-care subgroup analysis demonstrated that telemedicine interventions that significantly improved self-glucose monitoring and self-efficacy more than the control were found to have a higher reduction in HbA1c.

Research conclusions

Telemedicine is a useful and effective intervention for type 2 diabetes patients, which improves glycemic control and numerous other health outcomes significantly better than non-telemedicine interventions/controls. Subgroup analysis demonstrated that optimising the characteristics of telemedicine interventions may have a greater effect at improving health outcomes.

Research perspectives

In a world where telemedicine is more widely used than ever, it is important to ensure that these services are delivered at a high standard and benefit the participating patients. This study emphasises that telemedicine should be utilised as an effective approach to type 2 diabetes intervention.