年轻人的盐敏感性高血压:如何预测高血压性心脏病的风险?

IF 2.7 3区 医学 Q2 PERIPHERAL VASCULAR DISEASE
Cesare Cuspidi MD, Elisa Gherbesi MD, Marijana Tadic MD
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Two main hypotheses have been advanced in this long research journey, often opposed to each other. Indeed, it has been suggested that SSHT may be the consequence of impaired renal regulation of intravascular volume and, therefore, cardiac output (renal dysfunction theory) or, alternatively, resulting from altered regulation of vascular tone in resistance arteries (vaso-dysfuntion theory).<span><sup>2</sup></span></p><p>Although the criteria for detecting salt-sensitivity are not standardized, it has been reported that approximately 40% of hypertensive individuals and 20% of normotensive individuals are salt-sensitive.<span><sup>3</sup></span> Salt-sensitivity has been consistently shown to increase with age, which has been linked to impaired renal sodium handling and a decline in renal function, even in the absence of kidney disease, and with comorbidities associated with altered kidney and vascular function such as renal disease, diabetes, obesity and hypertension.<span><sup>4</sup></span> This condition affects females more frequently, regardless of menopause, Asian and African-American populations.<span><sup>5</sup></span> Whether salt-sensitivity increases the risk of cardiac and extracardiac organ damage (an intermediate step linking unhealthy risk factors to CV disease) independent of other risk factors, such as BP and obesity remains a subject of debate.<span><sup>6-8</sup></span> Even more unclear is the topic regarding clinical correlates and predictors of subclinical organ damage in patients with SSHT.</p><p>In this issue of the Journal Wan and colleagues<span><sup>9</sup></span> focus on an issue of great interest, namely the factors associated with left ventricular hypertrophy (LVH) in young patients with SSHT. Before addressing in detail the results of this study some more general considerations on current evidence in this research area and related topics may warrant some considerations.</p><p>The mechanisms underlying the development of LVH, a cardinal marker of target organ damage in the setting of hypertension have not been fully elucidated. Chronic BP overload load has long been considered the closest and most important factor responsible for this process. It has been consistently demonstrated, however, that BP, even when accurately measured with ambulatory monitoring that reflects the 24-h global BP load accounts for approximately 30%−40% of the observed variance of LV mass (LVM). A large body of experimental and clinical studies supports the view that neurohormones, growth factors and cytokines (i.e., angiotensin II, aldosterone, catecholamines endothelin I and insulin-like growth factor), in association with ethnic/genetic predisposition and unhealthy lifestyle habits such as excessive alcohol consumption, smoking and salt intake concur to trigger, maintain and worsen cardiac organ damage over time. In particular, growing and consistent evidence has accumulated on the key role of circulating and local renin–angiotensin–aldosterone system (RAAS) in developing of myocardial hypertrophy and fibrosis, regardless of the hemodynamic load on the heart.<span><sup>10</sup></span> A large amount of information provided by experimental and human investigations suggests a link between dietary sodium intake, SSHT and risk of LVH.<span><sup>11-13</sup></span> Seminal experimental studies showed that saline overload induces a progressive increase in LVM. Conversely, dietary salt restriction has been reported to regress LVH in hypertensive rats and similar findings have been obtained in patients with SSHT. Although the mechanisms of myocardial and fibrous tissue growth induced by sodium overload remain incompletely understood, activation of sympathetic nervous system and RAAS is believed to have a role in this process. High dietary salt intake also activates myocardial growth through hemodynamic mechanisms such as BP and volume overload and stimulates phospholipase C-activity mediated by platelet-derived growth factors. Focusing on the relationship between sodium intake and cardiac structure in the clinical setting a couple of studies carried out in general population samples deserve to be mentioned. The Strong Heart Family Study including 1065 young adults revealed that an increase in sodium/potassium ratio was related with higher LVM index in prehypertensive or hypertensive individuals but not in their normotensive counterparts.<span><sup>8</sup></span> The African-PREDICT study, aimed to assess whether LVM associates with sodium excretion in 681 young adults free from overt CV disease (41% men, 50% black), indicated that a higher salt intake may have an independent role in promoting an increase in LVM in the fraction of individuals with masked hypertension but not in normotensives.<span><sup>7</sup></span> However, clinical evidence on the association between salt-sensitivity and CV outcomes is still limited. Recently, a longitudinal study investigated the predictive value of the salt-sensitivity phenotype in the development of CV events and hypertensive target organ damage (i.e., LVH, albuminuria carotid atherosclerosis) in a small cohort of essential hypertensive patients.<span><sup>14</sup></span> During 16 years of follow-up the relative risk of developing CV events was 12-fold higher and the development of moderate to severe organ damage was 10 times higher in patients with SSHT than in their counterparts without it. It should be noted that interpreting of the findings provided by of the current literature on this topic we cannot ignore the fact that the definition of the SSHT phenotype is based on heterogeneous criteria, and the extent of the response above which the patient is considered to be salt-sensitive varies largely among studies. Among the various methods of testing for salt-sensitivity, the carefully controlled out-dietary protocol has been suggested to provide the highest test-retest repeatability for identifying salt-sensitive subjects.<span><sup>15</sup></span> The so-called “inpatient acute protocol” aimed to measure BP responses to furosemide immediately after venous infusion of saline solution might be viewed as an indirect test of salt-sensitivity. At the current time, unfortunately, tests for salt-sensitivity applicable in clinical practice have yet to be identified.<span><sup>16</sup></span></p><p>In their study, Wan and colleagues<span><sup>9</sup></span> salt-sensitivity was assessed using a modified acute saline test based on a 4-hour intravenous infusion of 2000 mL of 0.9% saline and followed by oral administration of furosemide at the standard dose of 40 mg. An increase in the mean arterial pressure (MAP) &gt; 5 mmHg after acute salt loading and/or a decrease in MAP &gt; 10 mmHg after furosemide (i.e., furosemide sensitivity test) were considered diagnostic criteria for SSHT. 580 patients (35% female) without severe cardiovascular and renal disease (22.5% obese, 18.7% treated with BP-lowering drugs and 9.8% with diabetes,) aged 18−45 who met the criteria for SSHT were included in the study and underwent blood biochemical examination, standard echocardiography and ambulatory BP monitoring. The prevalence of LVH (i.e., LVMI &gt; 115 g/m<sup>2</sup> in men and 95 g/m<sup>2</sup> in women) in the total population was 25.2%. It is worth noting that patients with LVH had markedly higher office systolic BP values ​​than patients with normal LVMI (183 ± 17 vs. 167 ± 17 mmHg) but unexpectedly similar mean 24-h SBP values (158 ± 21 vs. 156 ± 21 mmHg). Equally noteworthy is the fact, in line with many data provided by experimental studies in animals with SSHT, approximately 80% of patients had concentric LVH.<span><sup>17</sup></span> In this clinical context, Wan and colleagues<span><sup>9</sup></span> demonstrated that a nomogram including seven variables such as age, gender, office systolic BP, duration of hypertension, abdominal obesity, triglyceride-glucose index, and estimated glomerular filtration rate (eGFR) allowed to identify patients with LVH with a high coefficient of precision. This study deserves to be appreciated as it sheds light on the relationship between a still insufficiently studied hypertensive phenotype and subclinical cardiac organ damage. However, factors associated with LVH in this SSHT cohort are essentially no different than those consistently reported in the general hypertensive population, including to the greater exposure to the risk of subclinical organ damage in women.<span><sup>18</sup></span> Overall, the contribution of this study to current knowledge remains rather elusive due to some important methodological limitations. The cut-off used for classifying SSHT (i.e., a change in MAP of at least 5 mmHg) was lower than that generally applied in the setting of hypertension (i.e., 8−10 mmHg) thus including patients whose SSHT trait is borderline, often not reproducible, and therefore characterized by uncertain clinical significance. The lack of a hypertensive control group did not allow to prove whether and to what extent patients with SSHT have a higher prevalence of LVH compared to salt-resistant counterparts, to investigate differences in LV geometry and, more importantly, to compare the clinical variables linked to LVH. Although the study in developing the nomogram for the prediction of LVH considered variables routinely available in clinical practice, it would have been of extreme interest to include among the predictors nocturnal BP which is known to be associated with sodium sensitivity.<span><sup>19</sup></span></p><p>Further nonmethodological observations concern the following points. One, the extension of the results of this study to the general population of hypertensives with SSHT should be taken with extreme caution as focused on a cohort of hospitalized patients with high prevalence of severe hypertension. Although previous evidence suggests that women are more exposed to the pressure effects of sodium sensitivity,<span><sup>20</sup></span> they represented only about a third of the sample analyzed in the present study.<span><sup>9</sup></span></p><p>In conclusion, the study by Wan and colleagues<span><sup>9</sup></span> undoubtedly has the merit of having indirectly underlined the limits of the protocols to assess salt-sensitive and the need to develop reliable biomarkers in the near future that allow the identification of SSHT in daily clinical practice.</p><p>The authors declare no conflicts of interest.</p>","PeriodicalId":50237,"journal":{"name":"Journal of Clinical Hypertension","volume":"26 9","pages":"1110-1112"},"PeriodicalIF":2.7000,"publicationDate":"2024-07-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/jch.14876","citationCount":"0","resultStr":"{\"title\":\"Salt-sensitive hypertension in young people: How can we predict the risk of hypertensive heart disease?\",\"authors\":\"Cesare Cuspidi MD,&nbsp;Elisa Gherbesi MD,&nbsp;Marijana Tadic MD\",\"doi\":\"10.1111/jch.14876\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Salt-sensitive hypertension (SSHT) is characterized by blood pressure (BP) elevation in response to high dietary salt intake and is considered to increase the risk of cardiovascular (CV) disease and mortality beyond its effects on BP. This concept has been authoritatively underlined by a recent Scientific Statement of the American Heart Association (AHA) that defined SSHT as “a risk factor for CV mortality and morbidity, independent of and as powerful as BP.”<span><sup>1</sup></span></p><p>Despite since the beginning of the 20th century the relationship between sodium intake and BP is one of the most investigated aspects of the pathophysiology of hypertension, is not yet entirely clear how high salt intake is mechanistically associated with high BP. Two main hypotheses have been advanced in this long research journey, often opposed to each other. Indeed, it has been suggested that SSHT may be the consequence of impaired renal regulation of intravascular volume and, therefore, cardiac output (renal dysfunction theory) or, alternatively, resulting from altered regulation of vascular tone in resistance arteries (vaso-dysfuntion theory).<span><sup>2</sup></span></p><p>Although the criteria for detecting salt-sensitivity are not standardized, it has been reported that approximately 40% of hypertensive individuals and 20% of normotensive individuals are salt-sensitive.<span><sup>3</sup></span> Salt-sensitivity has been consistently shown to increase with age, which has been linked to impaired renal sodium handling and a decline in renal function, even in the absence of kidney disease, and with comorbidities associated with altered kidney and vascular function such as renal disease, diabetes, obesity and hypertension.<span><sup>4</sup></span> This condition affects females more frequently, regardless of menopause, Asian and African-American populations.<span><sup>5</sup></span> Whether salt-sensitivity increases the risk of cardiac and extracardiac organ damage (an intermediate step linking unhealthy risk factors to CV disease) independent of other risk factors, such as BP and obesity remains a subject of debate.<span><sup>6-8</sup></span> Even more unclear is the topic regarding clinical correlates and predictors of subclinical organ damage in patients with SSHT.</p><p>In this issue of the Journal Wan and colleagues<span><sup>9</sup></span> focus on an issue of great interest, namely the factors associated with left ventricular hypertrophy (LVH) in young patients with SSHT. Before addressing in detail the results of this study some more general considerations on current evidence in this research area and related topics may warrant some considerations.</p><p>The mechanisms underlying the development of LVH, a cardinal marker of target organ damage in the setting of hypertension have not been fully elucidated. Chronic BP overload load has long been considered the closest and most important factor responsible for this process. It has been consistently demonstrated, however, that BP, even when accurately measured with ambulatory monitoring that reflects the 24-h global BP load accounts for approximately 30%−40% of the observed variance of LV mass (LVM). A large body of experimental and clinical studies supports the view that neurohormones, growth factors and cytokines (i.e., angiotensin II, aldosterone, catecholamines endothelin I and insulin-like growth factor), in association with ethnic/genetic predisposition and unhealthy lifestyle habits such as excessive alcohol consumption, smoking and salt intake concur to trigger, maintain and worsen cardiac organ damage over time. In particular, growing and consistent evidence has accumulated on the key role of circulating and local renin–angiotensin–aldosterone system (RAAS) in developing of myocardial hypertrophy and fibrosis, regardless of the hemodynamic load on the heart.<span><sup>10</sup></span> A large amount of information provided by experimental and human investigations suggests a link between dietary sodium intake, SSHT and risk of LVH.<span><sup>11-13</sup></span> Seminal experimental studies showed that saline overload induces a progressive increase in LVM. Conversely, dietary salt restriction has been reported to regress LVH in hypertensive rats and similar findings have been obtained in patients with SSHT. Although the mechanisms of myocardial and fibrous tissue growth induced by sodium overload remain incompletely understood, activation of sympathetic nervous system and RAAS is believed to have a role in this process. High dietary salt intake also activates myocardial growth through hemodynamic mechanisms such as BP and volume overload and stimulates phospholipase C-activity mediated by platelet-derived growth factors. Focusing on the relationship between sodium intake and cardiac structure in the clinical setting a couple of studies carried out in general population samples deserve to be mentioned. The Strong Heart Family Study including 1065 young adults revealed that an increase in sodium/potassium ratio was related with higher LVM index in prehypertensive or hypertensive individuals but not in their normotensive counterparts.<span><sup>8</sup></span> The African-PREDICT study, aimed to assess whether LVM associates with sodium excretion in 681 young adults free from overt CV disease (41% men, 50% black), indicated that a higher salt intake may have an independent role in promoting an increase in LVM in the fraction of individuals with masked hypertension but not in normotensives.<span><sup>7</sup></span> However, clinical evidence on the association between salt-sensitivity and CV outcomes is still limited. Recently, a longitudinal study investigated the predictive value of the salt-sensitivity phenotype in the development of CV events and hypertensive target organ damage (i.e., LVH, albuminuria carotid atherosclerosis) in a small cohort of essential hypertensive patients.<span><sup>14</sup></span> During 16 years of follow-up the relative risk of developing CV events was 12-fold higher and the development of moderate to severe organ damage was 10 times higher in patients with SSHT than in their counterparts without it. It should be noted that interpreting of the findings provided by of the current literature on this topic we cannot ignore the fact that the definition of the SSHT phenotype is based on heterogeneous criteria, and the extent of the response above which the patient is considered to be salt-sensitive varies largely among studies. Among the various methods of testing for salt-sensitivity, the carefully controlled out-dietary protocol has been suggested to provide the highest test-retest repeatability for identifying salt-sensitive subjects.<span><sup>15</sup></span> The so-called “inpatient acute protocol” aimed to measure BP responses to furosemide immediately after venous infusion of saline solution might be viewed as an indirect test of salt-sensitivity. At the current time, unfortunately, tests for salt-sensitivity applicable in clinical practice have yet to be identified.<span><sup>16</sup></span></p><p>In their study, Wan and colleagues<span><sup>9</sup></span> salt-sensitivity was assessed using a modified acute saline test based on a 4-hour intravenous infusion of 2000 mL of 0.9% saline and followed by oral administration of furosemide at the standard dose of 40 mg. An increase in the mean arterial pressure (MAP) &gt; 5 mmHg after acute salt loading and/or a decrease in MAP &gt; 10 mmHg after furosemide (i.e., furosemide sensitivity test) were considered diagnostic criteria for SSHT. 580 patients (35% female) without severe cardiovascular and renal disease (22.5% obese, 18.7% treated with BP-lowering drugs and 9.8% with diabetes,) aged 18−45 who met the criteria for SSHT were included in the study and underwent blood biochemical examination, standard echocardiography and ambulatory BP monitoring. The prevalence of LVH (i.e., LVMI &gt; 115 g/m<sup>2</sup> in men and 95 g/m<sup>2</sup> in women) in the total population was 25.2%. It is worth noting that patients with LVH had markedly higher office systolic BP values ​​than patients with normal LVMI (183 ± 17 vs. 167 ± 17 mmHg) but unexpectedly similar mean 24-h SBP values (158 ± 21 vs. 156 ± 21 mmHg). Equally noteworthy is the fact, in line with many data provided by experimental studies in animals with SSHT, approximately 80% of patients had concentric LVH.<span><sup>17</sup></span> In this clinical context, Wan and colleagues<span><sup>9</sup></span> demonstrated that a nomogram including seven variables such as age, gender, office systolic BP, duration of hypertension, abdominal obesity, triglyceride-glucose index, and estimated glomerular filtration rate (eGFR) allowed to identify patients with LVH with a high coefficient of precision. This study deserves to be appreciated as it sheds light on the relationship between a still insufficiently studied hypertensive phenotype and subclinical cardiac organ damage. However, factors associated with LVH in this SSHT cohort are essentially no different than those consistently reported in the general hypertensive population, including to the greater exposure to the risk of subclinical organ damage in women.<span><sup>18</sup></span> Overall, the contribution of this study to current knowledge remains rather elusive due to some important methodological limitations. The cut-off used for classifying SSHT (i.e., a change in MAP of at least 5 mmHg) was lower than that generally applied in the setting of hypertension (i.e., 8−10 mmHg) thus including patients whose SSHT trait is borderline, often not reproducible, and therefore characterized by uncertain clinical significance. The lack of a hypertensive control group did not allow to prove whether and to what extent patients with SSHT have a higher prevalence of LVH compared to salt-resistant counterparts, to investigate differences in LV geometry and, more importantly, to compare the clinical variables linked to LVH. Although the study in developing the nomogram for the prediction of LVH considered variables routinely available in clinical practice, it would have been of extreme interest to include among the predictors nocturnal BP which is known to be associated with sodium sensitivity.<span><sup>19</sup></span></p><p>Further nonmethodological observations concern the following points. One, the extension of the results of this study to the general population of hypertensives with SSHT should be taken with extreme caution as focused on a cohort of hospitalized patients with high prevalence of severe hypertension. 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引用次数: 0

摘要

8 非洲-PREDICT 研究旨在评估 681 名无明显心血管疾病的年轻成年人(41% 为男性,50% 为黑人)的左心室容积是否与钠排泄量有关,研究结果表明,较高的盐摄入量可能会在促进部分假性高血压患者的左心室容积增加方面发挥独立作用,但在正常血压者中则不会。最近,一项纵向研究调查了盐敏感表型在一小批本质性高血压患者中对 CV 事件和高血压靶器官损害(即 LVH、白蛋白尿、颈动脉粥样硬化)发生的预测价值。应该指出的是,在解释目前有关这一主题的文献所提供的研究结果时,我们不能忽视这样一个事实,即 SSHT 表型的定义是基于不同的标准,而且不同研究认为患者对盐敏感的反应程度也大不相同。15 所谓的 "住院急性方案 "旨在静脉输注生理盐水后立即测量血压对呋塞米的反应,可被视为盐敏感性的间接测试。16 Wan 及其同事9 在他们的研究中使用了一种改良的急性生理盐水试验来评估盐敏感性,该试验基于 4 小时静脉输注 2000 毫升 0.9% 生理盐水,然后口服 40 毫克标准剂量的呋塞米。急性盐负荷后平均动脉压(MAP)升高 &gt; 5 mmHg 和/或服用呋塞米后平均动脉压降低 &gt; 10 mmHg(即呋塞米敏感试验)被视为 SSHT 的诊断标准。研究共纳入了 580 名年龄在 18-45 岁之间、无严重心血管和肾脏疾病(22.5% 肥胖、18.7% 接受降压药治疗、9.8% 患有糖尿病)、符合 SSHT 诊断标准的患者(35% 女性),并对其进行了血液生化检查、标准超声心动图检查和动态血压监测。总人口中 LVH(即 LVMI 为 115 g/m2 (男性)和 95 g/m2 (女性))的患病率为 25.2%。值得注意的是,LVH 患者的办公室收缩压值明显高于 LVMI 正常的患者(183 ± 17 vs. 167 ± 17 mmHg),但 24 小时收缩压平均值却出乎意料地相似(158 ± 21 vs. 156 ± 21 mmHg)。同样值得注意的是,与 SSHT 动物实验研究提供的许多数据一致,约 80% 的患者具有同心型 LVH。17 在此临床背景下,Wan 及其同事9 证实,包括年龄、性别、办公室收缩压、高血压持续时间、腹部肥胖、甘油三酯-葡萄糖指数和估计肾小球滤过率(eGFR)等七个变量在内的提名图能够以较高的精确系数识别 LVH 患者。这项研究揭示了研究尚不充分的高血压表型与亚临床心脏器官损伤之间的关系,值得赞赏。然而,SSHT 队列中与 LVH 相关的因素与普通高血压人群中的相关因素基本无异,包括女性更容易受到亚临床器官损害的影响。18 总体而言,由于一些重要的方法学局限性,这项研究对当前知识的贡献仍然相当有限。用于划分 SSHT 的临界值(即 MAP 变化至少 5 mmHg)低于通常用于高血压的临界值(即 8-10 mmHg),因此包括了 SSHT 特征不明确的患者,这些患者通常不能重复,因此临床意义不确定。由于缺乏高血压对照组,因此无法证明 SSHT 患者是否以及在多大程度上比耐盐性患者的 LVH 患病率更高,也无法研究 LV 几何形状的差异,更重要的是,无法比较与 LVH 相关的临床变量。尽管该研究在制定预测 LVH 的提名图时考虑了临床实践中的常规变量,但如果能将夜间血压纳入预测因素,则会引起极大的兴趣,因为夜间血压与钠敏感性相关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Salt-sensitive hypertension in young people: How can we predict the risk of hypertensive heart disease?

Salt-sensitive hypertension (SSHT) is characterized by blood pressure (BP) elevation in response to high dietary salt intake and is considered to increase the risk of cardiovascular (CV) disease and mortality beyond its effects on BP. This concept has been authoritatively underlined by a recent Scientific Statement of the American Heart Association (AHA) that defined SSHT as “a risk factor for CV mortality and morbidity, independent of and as powerful as BP.”1

Despite since the beginning of the 20th century the relationship between sodium intake and BP is one of the most investigated aspects of the pathophysiology of hypertension, is not yet entirely clear how high salt intake is mechanistically associated with high BP. Two main hypotheses have been advanced in this long research journey, often opposed to each other. Indeed, it has been suggested that SSHT may be the consequence of impaired renal regulation of intravascular volume and, therefore, cardiac output (renal dysfunction theory) or, alternatively, resulting from altered regulation of vascular tone in resistance arteries (vaso-dysfuntion theory).2

Although the criteria for detecting salt-sensitivity are not standardized, it has been reported that approximately 40% of hypertensive individuals and 20% of normotensive individuals are salt-sensitive.3 Salt-sensitivity has been consistently shown to increase with age, which has been linked to impaired renal sodium handling and a decline in renal function, even in the absence of kidney disease, and with comorbidities associated with altered kidney and vascular function such as renal disease, diabetes, obesity and hypertension.4 This condition affects females more frequently, regardless of menopause, Asian and African-American populations.5 Whether salt-sensitivity increases the risk of cardiac and extracardiac organ damage (an intermediate step linking unhealthy risk factors to CV disease) independent of other risk factors, such as BP and obesity remains a subject of debate.6-8 Even more unclear is the topic regarding clinical correlates and predictors of subclinical organ damage in patients with SSHT.

In this issue of the Journal Wan and colleagues9 focus on an issue of great interest, namely the factors associated with left ventricular hypertrophy (LVH) in young patients with SSHT. Before addressing in detail the results of this study some more general considerations on current evidence in this research area and related topics may warrant some considerations.

The mechanisms underlying the development of LVH, a cardinal marker of target organ damage in the setting of hypertension have not been fully elucidated. Chronic BP overload load has long been considered the closest and most important factor responsible for this process. It has been consistently demonstrated, however, that BP, even when accurately measured with ambulatory monitoring that reflects the 24-h global BP load accounts for approximately 30%−40% of the observed variance of LV mass (LVM). A large body of experimental and clinical studies supports the view that neurohormones, growth factors and cytokines (i.e., angiotensin II, aldosterone, catecholamines endothelin I and insulin-like growth factor), in association with ethnic/genetic predisposition and unhealthy lifestyle habits such as excessive alcohol consumption, smoking and salt intake concur to trigger, maintain and worsen cardiac organ damage over time. In particular, growing and consistent evidence has accumulated on the key role of circulating and local renin–angiotensin–aldosterone system (RAAS) in developing of myocardial hypertrophy and fibrosis, regardless of the hemodynamic load on the heart.10 A large amount of information provided by experimental and human investigations suggests a link between dietary sodium intake, SSHT and risk of LVH.11-13 Seminal experimental studies showed that saline overload induces a progressive increase in LVM. Conversely, dietary salt restriction has been reported to regress LVH in hypertensive rats and similar findings have been obtained in patients with SSHT. Although the mechanisms of myocardial and fibrous tissue growth induced by sodium overload remain incompletely understood, activation of sympathetic nervous system and RAAS is believed to have a role in this process. High dietary salt intake also activates myocardial growth through hemodynamic mechanisms such as BP and volume overload and stimulates phospholipase C-activity mediated by platelet-derived growth factors. Focusing on the relationship between sodium intake and cardiac structure in the clinical setting a couple of studies carried out in general population samples deserve to be mentioned. The Strong Heart Family Study including 1065 young adults revealed that an increase in sodium/potassium ratio was related with higher LVM index in prehypertensive or hypertensive individuals but not in their normotensive counterparts.8 The African-PREDICT study, aimed to assess whether LVM associates with sodium excretion in 681 young adults free from overt CV disease (41% men, 50% black), indicated that a higher salt intake may have an independent role in promoting an increase in LVM in the fraction of individuals with masked hypertension but not in normotensives.7 However, clinical evidence on the association between salt-sensitivity and CV outcomes is still limited. Recently, a longitudinal study investigated the predictive value of the salt-sensitivity phenotype in the development of CV events and hypertensive target organ damage (i.e., LVH, albuminuria carotid atherosclerosis) in a small cohort of essential hypertensive patients.14 During 16 years of follow-up the relative risk of developing CV events was 12-fold higher and the development of moderate to severe organ damage was 10 times higher in patients with SSHT than in their counterparts without it. It should be noted that interpreting of the findings provided by of the current literature on this topic we cannot ignore the fact that the definition of the SSHT phenotype is based on heterogeneous criteria, and the extent of the response above which the patient is considered to be salt-sensitive varies largely among studies. Among the various methods of testing for salt-sensitivity, the carefully controlled out-dietary protocol has been suggested to provide the highest test-retest repeatability for identifying salt-sensitive subjects.15 The so-called “inpatient acute protocol” aimed to measure BP responses to furosemide immediately after venous infusion of saline solution might be viewed as an indirect test of salt-sensitivity. At the current time, unfortunately, tests for salt-sensitivity applicable in clinical practice have yet to be identified.16

In their study, Wan and colleagues9 salt-sensitivity was assessed using a modified acute saline test based on a 4-hour intravenous infusion of 2000 mL of 0.9% saline and followed by oral administration of furosemide at the standard dose of 40 mg. An increase in the mean arterial pressure (MAP) > 5 mmHg after acute salt loading and/or a decrease in MAP > 10 mmHg after furosemide (i.e., furosemide sensitivity test) were considered diagnostic criteria for SSHT. 580 patients (35% female) without severe cardiovascular and renal disease (22.5% obese, 18.7% treated with BP-lowering drugs and 9.8% with diabetes,) aged 18−45 who met the criteria for SSHT were included in the study and underwent blood biochemical examination, standard echocardiography and ambulatory BP monitoring. The prevalence of LVH (i.e., LVMI > 115 g/m2 in men and 95 g/m2 in women) in the total population was 25.2%. It is worth noting that patients with LVH had markedly higher office systolic BP values ​​than patients with normal LVMI (183 ± 17 vs. 167 ± 17 mmHg) but unexpectedly similar mean 24-h SBP values (158 ± 21 vs. 156 ± 21 mmHg). Equally noteworthy is the fact, in line with many data provided by experimental studies in animals with SSHT, approximately 80% of patients had concentric LVH.17 In this clinical context, Wan and colleagues9 demonstrated that a nomogram including seven variables such as age, gender, office systolic BP, duration of hypertension, abdominal obesity, triglyceride-glucose index, and estimated glomerular filtration rate (eGFR) allowed to identify patients with LVH with a high coefficient of precision. This study deserves to be appreciated as it sheds light on the relationship between a still insufficiently studied hypertensive phenotype and subclinical cardiac organ damage. However, factors associated with LVH in this SSHT cohort are essentially no different than those consistently reported in the general hypertensive population, including to the greater exposure to the risk of subclinical organ damage in women.18 Overall, the contribution of this study to current knowledge remains rather elusive due to some important methodological limitations. The cut-off used for classifying SSHT (i.e., a change in MAP of at least 5 mmHg) was lower than that generally applied in the setting of hypertension (i.e., 8−10 mmHg) thus including patients whose SSHT trait is borderline, often not reproducible, and therefore characterized by uncertain clinical significance. The lack of a hypertensive control group did not allow to prove whether and to what extent patients with SSHT have a higher prevalence of LVH compared to salt-resistant counterparts, to investigate differences in LV geometry and, more importantly, to compare the clinical variables linked to LVH. Although the study in developing the nomogram for the prediction of LVH considered variables routinely available in clinical practice, it would have been of extreme interest to include among the predictors nocturnal BP which is known to be associated with sodium sensitivity.19

Further nonmethodological observations concern the following points. One, the extension of the results of this study to the general population of hypertensives with SSHT should be taken with extreme caution as focused on a cohort of hospitalized patients with high prevalence of severe hypertension. Although previous evidence suggests that women are more exposed to the pressure effects of sodium sensitivity,20 they represented only about a third of the sample analyzed in the present study.9

In conclusion, the study by Wan and colleagues9 undoubtedly has the merit of having indirectly underlined the limits of the protocols to assess salt-sensitive and the need to develop reliable biomarkers in the near future that allow the identification of SSHT in daily clinical practice.

The authors declare no conflicts of interest.

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来源期刊
Journal of Clinical Hypertension
Journal of Clinical Hypertension PERIPHERAL VASCULAR DISEASE-
CiteScore
5.80
自引率
7.10%
发文量
191
审稿时长
4-8 weeks
期刊介绍: The Journal of Clinical Hypertension is a peer-reviewed, monthly publication that serves internists, cardiologists, nephrologists, endocrinologists, hypertension specialists, primary care practitioners, pharmacists and all professionals interested in hypertension by providing objective, up-to-date information and practical recommendations on the full range of clinical aspects of hypertension. Commentaries and columns by experts in the field provide further insights into our original research articles as well as on major articles published elsewhere. Major guidelines for the management of hypertension are also an important feature of the Journal. Through its partnership with the World Hypertension League, JCH will include a new focus on hypertension and public health, including major policy issues, that features research and reviews related to disease characteristics and management at the population level.
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