Raised blood pressure is the world’s leading cause of premature death [1, 2]. Over 1.13 billion people globally have elevated blood pressure with two-thirds of them living in low- and middle-income countries; yet fewer than 1 in 5 people have their blood pressure levels under control [3]. Indeed, decreasing the prevalence of elevated blood pressure globally is one of the key targets of the World Health Organization’s Global Action Plan for 2013 to 2020 to reduce premature cardiovascular disease (CVD) deaths by 2025 [4]. Modifying this risk through pharmacologic lowering of raised blood pressure also plays an important strategy to reduce the burden of CVD. Findings from several randomised controlled trials (RCT) conducted in the past few decades across different countries have shown that pharmacologic lowering of blood pressure is effective in reducing the risk of CVD [5•, 6‐12]. These beneficial effects have been reported to be consistent across major antihypertensive drug classes, and the relative effects on cardiovascular outcomes are broadly proportional to the magnitude of blood pressure reduction [5•, 13]. Despite the existing and robust evidence on the efficacy of blood pressure–lowering treatment, major controversies remain particularly with regards to treatment strategies, such as the appropriate blood pressure threshold to start pharmacologic treatment, the blood pressure to target when on treatment, and whether these strategies should differ depending on an individual’s history of CVD and baseline blood pressure. These uncertainties have been reflected in differences in certain aspects of clinical guidelines in the management of raised blood pressure. [14‐16].

In this paper, we explore some of the earlier findings that have established the importance of raised blood pressure as a risk factor of CVD and describe observations that gave rise to uncertainties in the management of raised blood pressure. We will show reports demonstrating the efficacy of blood pressure–lowering drug treatment, and highlight findings from recent studies that examined the efficacy across strata of baseline blood pressure in people with and without prior CVD. We will then discuss how recent evidence addressed uncertainties in blood pressure–lowering treatment strategies. Finally, we will discuss and show future directions that can help inform clinical management of people with raised blood pressure.

Observations from prospectively followed cohorts of community-dwelling persons, who were usually free of known cardiovascular disease, have informed the importance of elevated blood pressure as a risk factor of vascular conditions. Investigations from the Framingham Study, which originally recruited 5209 men and women aged 30 to 62 years in 1948 who were then prospectively followed, have helped demonstrate the relationship between elevated blood pressure and the risks of incident coronary heart disease and stroke [17•, 18•, 19, 20]. While findings from the Framingham Study have contributed to establishing raised blood pressure as a risk factor of CVD, the size of the study was too small to allow reliable characterisation of the risk across a wide range of blood pressure level. Several decades after the Framingham Study began, other population-based cohorts were formed, which helped to refine our understanding on the impact of elevated blood pressure on vascular disease risk. By combining data from several of these prospective studies, robust findings supported the earlier observations indicating that, in people without prior CVD, raised blood pressure increases the risk of CVD [21•]. This association was seen across the population range of blood pressure, without any evidence that the risk is limited to those with high values, such as in hypertension, nor was there any observed elevation in the risk in the lower end of the population distribution of blood pressure. These findings have been extended by the Prospective Studies Collaboration by showing that this association is consistent across middle to older age groups [22•]. This pattern in the association is not limited to cohort studies with standardised clinical measurements. Using data extracted from routine clinical practice settings has shown similar findings [23•]. In these large-scale prospective studies, there has been no blood pressure level below which the association with CVD risk is no longer valid. That is, there is a continuous gradient in the risk of CVD with increasing blood pressure level; conversely, CVD risk falls with lower blood pressure levels.

In contrast, observations of the association between blood pressure and CVD seem to be different in people who have had a prior vascular disease [24, 25]. For example, in patients with a stable coronary artery disease, the risk of developing a composite outcome of cardiovascular death, myocardial infarction, or stroke has been reported to increase with higher blood pressure only in people whose usual systolic blood pressure was 130 mmHg or higher; below this blood pressure threshold, the CVD risk increased with lower blood pressure levels [24]. This relationship has been commonly described as a J-shaped curve, and raises a controversial implication in that, unlike the observations involving incident outcomes, lowering the blood pressure to a level below a certain threshold may prove to be harmful for certain patient groups, such as those who already had CVD previously.

The contrasting observations between population-based and patient cohorts are difficult to resolve given that observational studies remain prone to residual confounding. In addition, the risk associated with high blood pressure levels seen in observational studies does not necessarily establish raised blood pressure as a modifiable risk factor. Randomised trials investigating the effects of pharmacological agents to lower blood pressure provide evidence for the unconfounded effects of blood pressure–lowering on CVD outcomes and can demonstrate that such treatment can modify the risk associated with elevated blood pressure. In a meta-analysis based on published data from these trials, the effect of lowering systolic blood pressure by 10 mmHg resulted in a proportional reduction in the risk of major cardiovascular events by 20% (95% confidence interval [CI], 17 to 23%) [5•]. There was no significant heterogeneity in the effect according to history of CVD or by baseline systolic blood pressure that ranged from < 130 to ≥ 160 mmHg. Although this and other meta-analyses have established the benefits of blood pressure–lowering, determining the treatment effects among subgroups defined by considering more than one personal characteristic simultaneously is not possible by simply aggregating data from published reports [26, 27]. Thus, to correctly classify people according to their history of CVD as well as by their baseline blood pressure level, individual-level information on these factors is needed.

The Blood Pressure–Lowering Treatment Trialists’ Collaboration (BPLTTC), established in 1995, is a global collaboration of principal investigators and research scientists investigating the effects of blood pressure–lowering drug treatment on CVD and mortality through a series of individual participant-level data (IPD) meta-analyses (www.​bplttc.​org). The current phase of the BPLTTC has focused on investigating the stratified effects of blood pressure–lowering treatment on major cardiovascular events, other less commonly reported vascular outcomes, and safety outcomes [28]. The collaboration currently includes 52 trials with over 360,000 participants, which forms the largest randomised evidence for blood pressure–lowering treatments to date. In a recent report, the collaboration investigated the benefits of blood pressure–lowering treatment in reducing major cardiovascular outcomes (stroke, myocardial infarction, ischaemic heart disease, or heart failure causing death or requiring hospitalisation) in people with and without prior CVD as well as by baseline blood pressure [29••]. This specific study, based on 48 RCTs with relevant data, included 344,716 participants with a mean age of 65 years.

Nearly a third of the study participants had a known CVD event previously, and there was little difference in the age at baseline between participants with and without a history of CVD. However, baseline systolic/diastolic blood pressure was higher in the latter (157/89 mmHg) than in the former group (146/84 mmHg). Over a median follow-up of 4.2 years, 42,324 participants (12.3%) developed a major cardiovascular event. The achieved blood pressure reduction differed across trials, largely depending on the study design. Since the relative risk reduction was proportional to the magnitude of achieved blood pressure reduction (Fig. 1A), and that treatment effects are known to be largely mediated through blood pressure reduction [25], the relative risk estimates were standardised to a reduction in systolic blood pressure of 5 mmHg.

Many of the prevailing questions surrounding the clinical management of raised blood pressure relate to the blood pressure threshold at which to initiate pharmacotherapy, and, in determining treatment goals, how low should the blood pressure be reduced to.

Recent studies being led by the BPLTTC have addressed several uncertainties surrounding pharmacotherapy to lower blood pressure, in particular, examining stratified treatment effects according to different patient characteristics. To date, the BPLTTC has reported stratified effects according to a wide range of baseline blood pressure in people with and without previous cardiovascular disease, in middle-aged adults and older individuals, and in those with and without previous atrial fibrillation. Future investigations from the BPLTTC will consider other patient characteristics, such as history of diabetes and renal disease. There is a need for further work to understand treatment effects on other important vascular and non-vascular health outcomes, such as peripheral vascular disease, cognitive function impairment, and bone fractures. Understanding the wide-ranging benefits of blood pressure–lowering treatment may help provide informed discussions on therapeutic options and preferences between patients and clinicians.

Risk-based approaches for determining treatment strategies need further exploration. Some of the multivariable models to estimate an individual’s risk typically use information on personal characteristics, lifestyle, and clinical factors, such as age, sex, smoking status, blood pressure, lipids, and body size, to quantify the probability of developing an event, for example, in the next 10 years. Among the commonly used equations to estimate a patient’s absolute CVD risk at baseline include the Framingham Risk Scores [52], Pooled Cohort Equations [53], SCORE [54], and QRISK [55]. However, data-driven models are increasingly used in health care risk prediction tasks. For example, the use of deep learning algorithms to analyse data extracted from large-scale electronic health records has been reported to have better predictive capacity for vascular health outcomes than various data-driven algorithms [56‐58]. Deep learning models may be better at defining at-risk groups which might be relevant in evaluating any heterogeneity of treatment effects that are difficult to identify given conventional analytical methods and when using available trials data. Data-driven approaches may provide novel ways to help identify groups of people with the most and least to gain from blood pressure–lowering treatment for a given age, sex, ethnicity, or health status during a particular period in the person’s life course. However, whether a risk-based approach, based on these novel data-driven models, makes a substantive difference in identifying people who are most likely to benefit from blood pressure–lowering medications compared to commonly used risk assessment tools remains to be seen.

There is also a need to further explore the use of combinations of different drug classes and even new types of drugs to lower blood pressure. A once-daily single pill with low doses of different classes of blood pressure–lowering drugs could be a promising pharmacotherapeutic strategy if it could optimally lower blood pressure as well as cause minimal adverse events [59]. Moreover, it might also be worth exploring novel treatments that could achieve greater blood pressure reduction than can be achieved by current therapies, be these new classes of pharmacologic agents or non-pharmacologic interventions.

Pharmacologic lowering of raised blood pressure is effective in the primary and secondary prevention of CVD. These effects are seen across a wide range of baseline blood pressure levels and not limited to those with high values only. However, clinical decision-making to treat raised blood pressure should include several considerations, including the level of blood pressure reduction that is feasible to achieve given the current evidence on the treatment effects of trialled drugs and therapeutic regimens. Conventional approaches that use blood pressure levels to assess the need for pharmacologic interventions to manage raised blood pressure may limit access to such treatment for those whose blood pressure levels do not reach the threshold for ‘abnormally high’ levels yet are at high risk of developing CVD. Alternative strategies to guide treatment decisions could be based on thresholds based on background CVD risk rather than on blood pressure levels. While there are several existing ways to assess background CVD risk, data-driven models, as applied to large-scale health data, may provide novel approaches to estimate the predicted absolute CVD risk at baseline. Future work should further compare and evaluate these risk-modifying approaches to therapy against standard strategies based on blood pressure thresholds in different populations and health care settings. Whichever strategy is used, discussions between patients and clinicians should include treatment effects on other important but less commonly reported vascular and non-vascular disease outcomes, as well as safety outcomes. Finally, future investigations should aim to develop novel pharmacological and non-pharmacological interventions that can achieve greater effects in blood pressure lowering but with minimal, or even less, adverse effects, than can be achieved with existing therapies.