Hypertension is a major risk factor for many diseases. World Health Organization data show that, worldwide, 33% of people aged 30 to 79 years have hypertension, constituting 1.3 billion people. In China, the prevalence is 27.9% with 245 million patients, but only 41% are aware, 34.9% are treated, and 11% have controlled blood pressure [1]. Poor treatment adherence is the main reason for uncontrolled blood pressure. The World Health Organization defines treatment adherence as following the physician’s plan, including medication and lifestyle. Nonadherence makes it 2.15 times harder to control blood pressure, 2.08 times more likely to have complications, and 1.38 times more likely to die [2]. Thus, improving hypertension management is urgent and important.

Despite significant advances in medication accessibility, treatment adherence remains suboptimal. This nonadherence crisis necessitates a paradigm shift toward nonpharmacological determinants of treatment outcomes. Informational support is an important part of social support, defined as the strategic delivery of evidence-based guidance, therapeutic counseling, and health literacy interventions aimed at stress mitigation and illness coping skill development [3]. This knowledge translation process empowers patients to navigate complex treatment regimens while optimizing self-efficacy in chronic disease management, simultaneously alleviating patients’ anxiety and perceived uncertainty to enhance therapeutic adherence.

There is emerging evidence suggesting that nontailored informational support modalities may engender maladaptive health beliefs, undermining medication adherence through distorted risk-benefit perceptions [4] and, ultimately, compromising blood pressure trajectory stabilization [5]. A recent study published in the Journal of the American Medical Association demonstrated that SMS text message reminders for patients who delayed initiating cardiovascular medication supplementation did not enhance medication adherence or decrease clinical events at the 12-month follow-up [6]. Notwithstanding these gaps in delivery optimization, systematic reviews highlight promising yet inconsistent efficacy signs for dyadic communication strategies, particularly protocol-driven face-to-face follow-up (mean difference 1.00, 95% CI 0.46-1.54) [7] vs structured telephone consultations (risk ratio=1.30, 95% CI 1.07-1.59) [8].

However, the implementation pathways of informational support in hypertension management remain underexplored. Current clinical practices face several challenges: (1) fragmented health education models that lack systematic integration and refinement; (2) the provision of standardized informational support failing to account for patient individuality, resulting in inadequate attention to critical needs; and (3) overreliance on clinic-based in-person sessions. To address these gaps, this study developed a hierarchical progressive informational support framework. The integrated intervention synergizes personalized in-person follow-up (for trust building and rapport establishment) with telephone-delivered counseling, forming a dual-modality framework that has demonstrated potential efficacy in prior feasibility studies [9]. Therefore, we conducted this prospective single-arm study to assess the acceptability of the personalized informational support intervention and preliminary changes in clinical indicators to inform a future randomized controlled trial (RCT).

This study used a single-arm pretest-posttest design to explore the feasibility of personalized informational support for patients with hypertension. The primary objectives were to (1) assess the implementation feasibility of the intervention, (2) observe preliminary changes in therapeutic adherence and blood pressure control following the intervention, and (3) inform the design and sample size calculation for a future RCT.

A prospective, single-center, pretest-posttest study was conducted at the Cuqiao Community Health Service Center in Wuhou District, Chengdu. This study adopted a consecutive enrollment method targeting patients with hypertension visiting community clinics, with enrollment stopped after 100 participants were included. Recruitment began on May 25, 2019, and ended on June 15, 2019. This study adhered to the reporting content of the Transparent Reporting of Evaluations With Nonrandomized Designs guidelines.

The diagnostic criteria for hypertension were established as follows: (1) office-measured systolic blood pressure (SBP) of ≥140 mm Hg and/or diastolic blood pressure (DBP) of ≥90 mm Hg obtained through 3 separate measurements on different days and (2) documented history of hypertension with current use of antihypertensive medications, with confirmed diagnosis maintained even when SBP <140 mm Hg and/or DBP <90 mm Hg.

The inclusion and exclusion criteria are shown in Textbox 1.

In previous studies, an educational intervention by health care professionals was shown to reduce SBP by 8 mm Hg with a paired-difference SD of 22.86 mm Hg [10]. Using an α value of .05 (2 sided) and 80% power, a minimum of 65 participants was required. Accounting for 20% attrition, we planned to recruit 92 participants. A total of 100 people were recruited in the end.

This study explicitly took medication adherence as the primary outcome, with blood pressure, lifestyle adherence, and other blood test indicators as exploratory outcomes.

This single-center, pretest-posttest study involving human participants was reviewed and approved by the institutional review board (IRB) of the West China Hospital, Sichuan University (registration 2019; review 573). The IRB specifically evaluated the study design (self–pretest-posttest comparison) to ensure minimal risk to participants, focusing on the safety of the health education intervention and the confidentiality of personal health data.

Written informed consent was obtained from all participants before the baseline assessment. The consent form clearly explained (1) the study purpose (to evaluate the impact of a health behavior intervention on clinical and behavioral outcomes via self-comparison), (2) the procedures (baseline data collection; 3-month intervention, including health education manuals and dietary counseling; and postintervention follow-up), (3) the potential risks (eg, no improvement in outcomes and temporary inconvenience from data collection), and (4) participants’ rights (to withdraw at any time without affecting clinical care and access to their deidentified data summary). For participants with low literacy, verbal consent was obtained in the presence of a study nurse (witnessed and documented with the witness’s signature), as approved by the IRB.

All personal identifiable information (eg, names and medical record numbers) was removed at the time of data entry. Deidentified datasets were used for all analyses, ensuring that participants’ privacy was protected throughout the study.

All participants in this study volunteered to take part and received no financial compensation.

This study was registered with the Chinese Clinical Trial Registry under the identifier ChiCTR2000039621.

We enrolled 100 consecutive patients with hypertension from the general outpatient clinic of a community health care center between May 2019 and June 2019. All 100 patients completed the baseline assessment, 3 (3%) withdrew from the study, and 4 (4%) were lost to follow-up due to relocation. Hence, 93% (n=93) completed assessments at 3 months. Details are provided in Figure 2.

The mean age of the study participants was 60.88 (SD 10.43) years. Most were female (59/100, 59%) and married or cohabiting (96/100, 96%), had a high school education or lower (90/100, 90%), and were living with family (98/100, 98%). Details are provided in Table 2.

The medication adherence score exhibited a statistically significant improvement of 0.65 points (95% CI 0.38 to 0.91; P<.001) at 3 months after the intervention compared to baseline measurements. In contrast, the lifestyle adherence score exhibited a modest increase of 0.24 points (95% CI 0.17 to 0.64; P=.25) following the intervention.

Statistically significant differences were observed in the nutrition (P<.001), interpersonal relationships (P=.001), health responsibility (P=.001), and overall health-promoting behavior scores (P=.001) of patients with hypertension before vs after the intervention. However, no statistically significant differences were detected in the physical activity (P=.54), stress management (P=.14), and spiritual growth (P=.17) dimensions. Details are provided in Table 3.

The postintervention nocturnal blood pressure parameters exhibited statistically significant reductions, with SBP decreasing by 5.07 mm Hg (95% CI –8.12 to –2.01; P=.001) and DBP decreasing by 3.39 mm Hg (95% CI −5.12 to −1.67; P<.001). In contrast, no statistically significant alterations were observed in daytime SBP or DBP (P=.19 and P=.72, respectively), 24-hour ambulatory blood pressure metrics (SBP: P=.52; DBP: P=.76), waist circumference (Δ=–0.08 cm; P=.89), or BMI (Δ=0.27 kg/m²; P=.17) following the intervention protocol. Office blood pressure measurements, BMI, waist circumference data, and laboratory indicators are presented in Table 4, whereas ambulatory blood pressure monitoring results are illustrated in Figure 3.

According to social support theory, informational support enhances adherence by boosting health literacy (eg, helping patients understand how medications control blood pressure) and self-efficacy (eg, building confidence to manage side effects) [13]. Consistent with this, we observed clinically meaningful improvements in medication adherence scores. Notably, 73.1% (68/93) of the patients showed improved adherence, a rate comparable to that of recent RCTs of health literacy interventions [14]. While HLI scores increased nominally, this aligns with prior work showing that lifestyle modification is more challenging than medication adherence [15]. This may be attributed to the fact that the short-term benefits of changes in lifestyle are less pronounced than those of medications, which has also led patients to place less emphasis on long-term lifestyle modifications. This suggests that future research should pay greater attention to lifestyle changes, enhance the intensity of related interventions, extend intervention durations, and prioritize the monitoring of adherence to lifestyle interventions so as to achieve better intervention outcomes.

Traditional hypertension interventions often use one-off health education or target single groups, leading to low engagement [16]. The improvements in nutrition and interpersonal relationship scores in our study may be associated with the intervention. However, physical activity remained unchanged, likely because we did not include personalized tools such as activity trackers or weekly feedback—consistent with longitudinal studies highlighting exercise adherence as a persistent challenge. Future studies should integrate objective activity monitoring to bridge this gap.

Our study data revealed that enrolled community-dwelling patients with hypertension exhibited well-controlled blood pressure and other cardiovascular risk factors. This observation suggests potential associations with the socioeconomic characteristics of the study population: all participants were recruited from Chengdu’s first-tier economic zone, where robust primary care management systems and higher resident health literacy may be associated with optimized baseline risk factor control. Consequently, the intervention implemented in this study demonstrated limited potential for further improvement in clinical outcomes given that the population’s preexisting optimal management status may have created a ceiling effect for measurable therapeutic efficacy. Previous longitudinal cohort studies have indicated that clinically significant improvements in anthropometric parameters (eg, waist circumference and BMI) typically require a minimum of 6 months of sustained intervention to achieve detectable changes [17]. Additionally, each 1-cm reduction in waist circumference corresponds to a cumulative energy deficit of approximately 7700 kcal based on adipose tissue energy density estimates. Achieving such energy imbalance through lifestyle interventions typically requires ≥180 days, consistent with adipose tissue turnover kinetics [18]. Existing studies have confirmed that the cardiovascular benefits of nocturnal blood pressure dipping significantly surpass those of daytime blood pressure reduction [19]. Our study found that informational support was associated with marked improvements in nocturnal blood pressure. Although few recent studies have explored the intervention effects of social support on ambulatory blood pressure, previous research has corroborated our findings [20,21]. This aligns with previous theoretical studies on social support, potentially mediated by improved sleep quality [22], enhanced treatment adherence, and buffering of psychological stress [13,23], with informational support identified as the most significant predictor [24]. Therefore, the implementation of comprehensive informational support for patients with hypertension in community settings holds promise for reducing nocturnal blood pressure and improving cardiovascular outcomes.

Additionally, no statistically significant differences were observed between pre- and postintervention levels of clinical indicators such as blood glucose and lipids. This null effect may be attributable to the relatively brief duration of our intervention. Future research should lengthen intervention periods and increase intervention intensity to optimize effectiveness.

This study investigated the effects of informational support on medication adherence, blood pressure control, adoption of healthy lifestyles, and clinical indicators among patients with hypertension. The findings demonstrate significant clinical implications: observed improvements in patient adherence, nocturnal blood pressure, and select health behaviors may collectively contribute to reduced cardiovascular risk and enhanced quality of life.

Several limitations warrant consideration. First, while the prospective design addressed temporal relationships, the absence of a control group represents a critical issue that not only complicates causal inference but also makes it impossible to avoid the influence of confounding factors such as seasons. However, it is crucial to note that this feasibility pilot study aimed to generate preliminary data essential for designing methodologically robust large-scale trials. Second, there is potential reporting bias as self-reported measures constituted portions of the dataset. Third, recruitment from resource-advantaged communities within Chengdu may limit generalizability. Participants’ elevated health literacy and physicians’ structured management protocols likely yielded response patterns not fully representative of broader populations. Future investigations should prioritize multiregional sampling to enhance external validity.

In conclusion, this feasibility study indicates that delivering a structured informational support intervention in a community setting is feasible and acceptable. We observed promising preliminary changes in key outcomes such as medication adherence and nocturnal blood pressure. These findings, while preliminary, justify and inform the design of a full-scale RCT to rigorously evaluate the efficacy of this approach.