UNHEALTHY/POOR DIETS

There is accumulating evidence that links the high red meat consumption with a higher risk of poorly controlled BP and hypertension (Allen, Bhatia, Wood, Momin, & Allison, 2022). A systematic review and meta‐analysis of 28 prospective studies indicated a positive association between red meat, processed meat consumption as well as sugar‐sweetened beverages with the risk of hypertension. Indeed, an intake of 170 g/d of red meat, 35 g/d of processed meat, and 500 mL/d of sugar‐sweetened beverages was associated with a 78% increased risk of hypertension, compared to non‐consumption (Schwingshackl et al., 2017). Nevertheless, research on this subject was criticized for important methodological limitations (i.e., reverse causality, residual confounding, recall and reporting biases) (Allen et al., 2022).

The Western diet characterized by a high intake of saturated fats, refined carbohydrates, and sodium and a low intake of potassium is likely to lead to the development of hypertension through different mechanisms (Canale et al., 2021; Jama, Beale, Shihata, & Marques, 2019). The mechanisms that have been proposed include the vasoconstriction, impaired vasodilation, extracellular volume expansion, inflammation, increased sympathetic nervous system activity as well as gut dysbiosis. However, in a meta‐analysis of 27 studies (16 cohort studies and 11 cross‐sectional studies), the Western‐style pattern (high intake of red and/or processed meat, refined grains, sweets, high‐fat dairy products, butter, potatoes, and high‐fat gravy, and low intake of fruits and vegetables) was not associated with an increased risk of hypertension (Wang, Shen, & Liu, 2016). Researchers showed that body‐mass index (BMI) mediated the association between Western‐style pattern and the risk of hypertension, while supporting that other unknown or unmeasured potential confounders, which were not considered in their analyses could also affect this association (Wang et al., 2016).

SODIUM INTAKE

Globally, sodium intake ranges between 3.5 and 5.5 g/d (9–12 g/d of salt), with marked differences among countries (Grillo, Salvi, Coruzzi, Salvi, & Parati, 2019). About 11% of sodium intake results from salt added during cooking or at the table, while more than 75% is derived from salt added during the processing of foods (i.e., bread, salted meats, cereals, canned goods) and food preparation (i.e., fast‐food and restaurants) (Carey et al., 2018; Samadian, Dalili, & Jamalian, 2016). Although sodium is an essential nutrient for all humans, excessive sodium intake is an important determinant of hypertension (M. O’Donnell, Mente, & Yusuf, 2015; Whelton et al., 2012). Specifically, available evidence suggests a causal relationship between sodium intake and BP. Excessive sodium intake (>5 g/d sodium, i.e., 1 teaspoon/d of salt) is associated with an increased prevalence of hypertension and its cardiovascular complications (Grillo et al., 2019).

Excess sodium intake affects molecular pathways, thus leading to an increase in BP. Evidence shows that the BP response is based on the sensitivity in salt intake of individuals in the general population. This phenomenon is defined as salt‐sensitivity, and it is based on an increase or neutral effect in BP with a high salt diet. Research has shown that approximately 50% of patients with hypertension and 25% of people with normotension are salt‐sensitive. Many factors determine whether an individual is salt‐sensitive or salt‐resistant, such as co‐morbidities like kidney dysfunction and diabetes mellitus as well as older age, genetics, quality of diet, ethnicity, or body mass. Evidence supports that salt‐sensitivity is associated with an increased cardiovascular risk in both normotensive and hypertensive individuals (Bouchard et al., 2022; Grillo et al., 2019).

ALCOHOL INTAKE

There is a well‐documented positive linear association between alcohol abuse, BP, the prevalence of hypertension, and cardiovascular disease (Roerecke et al., 2017). Excess alcohol intake (>3 drinks/d for men and >2 drinks/d for women) is responsible for 5% to 30% of hypertension. Alcohol consumption is directly correlated with elevated BP (Mahmood et al., 2019). It seems that there are sex‐specific associations between alcohol consumption and the risk of hypertension. Indeed, several studies have documented that any alcohol consumption is associated with an increase hypertension risk in men, whereas 1‐2 drinks / day in women may not be that harmful, as there is an increased risk for higher consumption levels (Briasoulis, Agarwal, & Messerli, 2012; Fernández‐Solà, 2015; Roerecke et al., 2018).

WEIGHT LOSS

Weight loss either by adhering to a healthy diet, increasing physical activity, or reducing sedentariness, is considered a vital strategy for preventing or managing hypertension in adults with overweight and obesity and hypertension. Weight loss can attenuate the risks of hypertension and related co‐morbidities in this population, but further evidence is needed on the long‐term efficacy of this strategy (Valenzuela et al., 2021).

Α 2% to 3% weight loss may lead to improvements in cardiovascular disease risk factors (M. E. Hall et al., 2021). Achieving 5% to 10% of weight loss can lead to >5 and 4 mm Hg reduction in SBP and DBP, respectively (M. E. Hall et al., 2021; Unger et al., 2020). In a meta‐analysis of 25 RCTs including 4874 participants, a weight reduction of 5.1 kg reduced SBP by 4.4 mm Hg and DBP by 3.6 mm Hg (Neter, Stam, Kok, Grobbee, & Geleijnse, 2003). The expected reduction in SBP is 1 mm Hg for every kilogram of body weight lost (Neter et al., 2003).

The aim is to reduce body weight so as to achieve a normal BMI (approximately 20–25 kg/m² in individuals <60 years of age; higher in older patients) or an ideal body weight but even reduction of 1 Kg might be beneficial for lowering BP or managing hypertension for adults with overweight or obesity (Whelton et al., 2018; Perumareddi, 2019; Williams et al., 2018). Indeed, every 1 kg of weight loss may lead to 1 mm Hg reduction in BP (Stevens et al., 2001). Although the optimal BMI is unclear, maintenance of healthy body weight (BMI of approximately 20–25 kg/m² in individuals <60 years of age; higher in older patients) and waist circumference (<94 cm for men and <80 cm for women) is recommended for the treatment of hypertension. Weight loss can also improve the efficacy of medications for hypertension (Piepoli et al., 2016).

However, the evidence on the actual long‐term sustainability of lifestyle interventions aimed at reducing body weight is unclear, although combining energy‐restrictive diets and exercise interventions seems to maximize the likelihood of maintaining body‐weight reduction (Valenzuela et al., 2021).

SODIUM RESTRICTION

Sodium restriction not only decreases BP and hypertension incidence but is also associated with a reduction in cardiovascular morbidity and mortality (Whelton & He, 2014). Sodium reduction is highly recommended for preventing and managing hypertension. A meta‐analysis of 34 RCTs including 3230 participants showed that a mean reduction of 1.75 g/d sodium (4.4 g/d salt) caused a mean reduction of 4.2/2.1 mm Hg in SBP/DBP, with a more pronounced effect (−5.4/−2.8 mm Hg) in individuals with hypertension (F. J. He, Li, & MacGregor, 2013). Even lower amounts of sodium intake have been tried in otherwise healthy individuals for assessing the role of sodium restriction on BP. In a systematic review and meta‐analysis of 37 RCTs, reducing sodium intake (<2 g/day) led to a reduction of SBP and DBP by 3.5 and 1.8 mm Hg, respectively, with no significant adverse effect on blood lipids, catecholamines or renal function (Aburto et al., 2013). Moreover, in a meta‐analysis of 133 RCTs including 12,197 participants, each 50 mmol reduction in 24 hour sodium excretion was associated with a 1.10 mm Hg reduction in SBP and a 0.33 mm Hg reduction in DBP. Researchers showed a dose‐response relationship between the sodium restriction and the fall in BP, but this association was more pronounced in older people, those with higher initial BP, and non‐white populations (Huang et al., 2020).

In older adults with overweight or obesity, reduction in sodium intake (~1000 mg/d) combined with weight loss can also improve BP (Whelton et al., 1998). However, weight loss in the elderlies as mentioned in Chapter 10, should be made with caution as it may lead to loss of lean body mass and subsequent functional decline. Nevertheless, nonpharmacologic interventions in the elderly (TONE) including weight loss are not associated with an increase in all‐cause mortality and can be used for achieving BP improvements (Shea et al., 2011). Lowering salt intake to less than 1200 mg/d seems to be safe and beneficial (Aburto et al., 2013; Oliveros et al., 2020).

The WHO recommends sodium intake to be limited to approximately 2.0 g/d (5.0 g/d salt) in the general population (Organization World Health & World Health Organization, 2012), as well as to those with hypertension (Williams et al., 2018). According to the 2017 guidelines of the ACC/AHA, the optimal goal sodium intake is defined as <1500 mg/d, but a reduction of at least 1000 mg/d is desirable for most adults and especially for those with hypertension (Whelton et al., 2018).

Effective sodium reduction is not easy, and it is often difficult to determine which foods contain high salt levels. Patients with hypertension should be guided to reduce salt added when preparing foods and at the table and avoid consumption of salty foods (i.e., fast foods, soy sauce, canned foods, cheeses, bread, nuts, chips, and tomato sauces and many processed foods) (Perumareddi, 2019; Bouchard et al., 2022; Williams et al., 2018).

POTASSIUM INTAKE

Potassium excretion, as a marker of dietary intake, is inversely associated with BP. Increasing potassium intake either from diet or through a supplement can reduce BP in people with hypertension, without adverse effects (Burnier, 2019; Samadian et al., 2016).

Adults with hypertension should consume adequate amounts of dietary potassium to meet the dietary reference intake (DRI). Indeed, the 2017 ACC/AHA guidelines propose an increase in potassium intake, ideally through dietary modification (i.e., preference for foods high in potassium such as the consumption of meat, milk, fruits, and vegetables (Oparil et al., 2018; Samadian et al., 2016) and not from supplements (Whelton et al., 2018)). The suggested intake is 3500 to 5000 mg/d (Whelton et al., 2018).

However, if patients with hypertension are unable to meet the DRI for potassium through diet alone and there are no other co‐morbidities, potassium supplementation of up to 3700 mg/d may be recommended to reduce elevated BP (Lennon et al., 2017). Indeed, potassium supplementation up to approximately 3700 mg/d can reduce SBP and DBP by 3 to 13 and 0 to 8 mm Hg, respectively, in individuals with hypertension (Lennon et al., 2017). A meta‐analysis of 33 RCTs including 2609 participants demonstrated that potassium supplementation (≥60 mmol/d) reduced SBP and DBP by 4.4 mm Hg and 2.5 mm Hg, respectively, in individuals with hypertension (Whelton et al., 1998).

MAGNESIUM INTAKE

A meta‐analysis of nine prospective cohort studies including 180,566 participants supported an inverse dose‐response relationship between dietary magnesium intake and the risk of hypertension (Han et al., 2017). Similarly, inadequate levels of potassium may contribute to hypertension (Perumareddi, 2019).

Adequate amounts of dietary potassium are considered 3.5 to 5 g/d. In order to meet DRI and to control BP, patients with hypertension are recommended to consume foods high in potassium such as whole grains, green leafy vegetables, and nuts. However, the evidence assessing the relationship between magnesium intake either from food sources or via supplementation and BP in individuals with hypertension is weak. Based on an umbrella review of 16 meta‐analysis (36 RCTs and 19 observational studies), clinical data showed that magnesium supplementation was able to reduce SBP and DBP by ~2 mm Hg, which is probably of limited clinical meaning. Results from observational studies showed also a weak association between dietary intake of magnesium and incidence of hypertension. (Veronese et al., 2020). Nevertheless, magnesium supplementation of 240 to 1000 mg/d may be considered for patients who are unable to meet the DRI with food sources alone (Lennon et al., 2017), achieving a SBP and DBP reduction by 1.0 to 5.6 and 1.0 to 2.8 mm Hg, respectively (Lennon et al., 2017).

CALCIUM INTAKE

Several reviews have shown an inverse association between the intake of calcium and BP or hypertension (Cormick, Ciapponi, Cafferata, Cormick, & Belizán, 2022). An adequate intake of calcium should be encouraged to prevent hypertension (van Mierlo et al., 2006).

A meta‐analysis of eight prospective cohort studies including 248,398 participants with a follow‐up duration ranging from 2 to 10 years showed that higher dietary calcium intake is associated slightly with a lower risk of developing hypertension (Ahmad Jayedi & Zargar, 2019). A dietary calcium intake of ≥800 mg/d may lead to a reduction of SBP >4 mm Hg and DBP >2 mm Hg in individuals with hypertension, whereas calcium supplementation of 1000 to 1500 mg/d reduces SBP/DBP >3.0/2.5 mm Hg in individuals with hypertension.

Patients with hypertension should consume adequate amounts of dietary calcium, such as milk, yogurt, cheese, and almonds, to meet the DRI in order to control BP. Calcium supplementation of 1000 to 1500 mg/d may be considered for patients unable to meet the DRI with diet alone (Lennon et al., 2017).

OMEGA‐3 FATTY ACIDS

Many cohort studies and RCTs have shown associations between increased consumption of omega‐3 fatty acids and lowered BP in individuals with hypertension (Bercea, Cottrell, Tamagnini, & McNeish, 2021; Colussi, Catena, Novello, Bertin, & Sechi, 2017). A meta‐analysis of 70 RCTs examined the long‐chain omega‐3 fatty acids eicosapentaenoic acid (EPA; 20:5 n‐3) and docosahexaenoic acid (DHA; 22:6 n‐3) in relation to BP. Provision of ≥2 g/d EPA+DHA may lead to a reduction in SBP and DBP, with the strongest benefits observed among individuals with hypertension who are not on antihypertensive medication (Miller, Van Elswyk, & Alexander, 2014).