Cardiovascular risk assessment: The key path toward precision prevention

Q1 Medicine
Jianxin Li, Xiangfeng Lu
{"title":"Cardiovascular risk assessment: The key path toward precision prevention","authors":"Jianxin Li,&nbsp;Xiangfeng Lu","doi":"10.1002/cdt3.90","DOIUrl":null,"url":null,"abstract":"<p>Cardiovascular disease (CVD) is the most common noncommunicable disease and the leading cause of death globally.<span><sup>1</sup></span> It has resulted in enormous economic and social burdens, while posing a great challenge for the prevention and control of CVD worldwide, especially in China. Assessment and management of cardiovascular risk is the foundation of CVD prevention, and is strongly recommended by guidelines.<span><sup>2-4</sup></span> Additionally, it can help screen the target population who would benefit most from the lower-cost intervention, while informing them the cardiovascular risk, which will help in promoting self-management. It can also guide doctors in making logical management decisions, and implement precision prevention and treatment strategies to reduce the CVD burden.<span><sup>2, 4</sup></span> Therefore, it is a key approach in achieving the goals of “Good Health and Well-being” in the United Nations and “Healthy China 2030” in China. Here, we briefly highlight several advances in cardiovascular risk assessments.</p><p>The Framingham Heart Study introduced the term “risk factor” in 1961, and identified a series of risk factors of CVD subsequently, such as cholesterol, blood pressure, glucose, and obesity.<span><sup>5</sup></span> By integrating multiple conventional risk factors, a general cardiovascular risk instrument was further developed to assist in identifying and treating individuals at high risk.<span><sup>6</sup></span> Since the concept of cardiovascular risk assessment and stratification was adopted by the third Adult Treatment Panel of the National Cholesterol Education Program in 2001, it has led to the development of effective treatment and preventive strategies in clinical practice.</p><p>A systematic approach to cardiovascular risk assessment includes the collection of information to calculate the cardiovascular risk, identification of the target high-risk population, and implementation of individual management according to the risk level. Therefore, risk-prediction models are major components of risk-based CVD prevention and control efforts. Several cardiovascular risk models have been developed using conventional risk factors to assist in clinical practice, such as the Reynolds Risk Score<span><sup>7, 8</sup></span> and the Pooled Cohort Equations (PCE)<span><sup>9</sup></span> in the United States, the QRISK in the United Kingdom,<span><sup>10</sup></span> the ASSIGN Score in Scotland,<span><sup>11</sup></span> the Systematic Coronary Risk Evaluation (SCORE) model in Europe,<span><sup>12</sup></span> and the Prediction for Atherosclerotic CVD Risk in China (China-PAR) equations.<span><sup>13</sup></span> In addition, World Health Organization has derived the risk prediction charts for 21 Global Burden of Disease regions to facilitate the risk-based CVD prevention in low- and middle-income countries.<span><sup>4</sup></span> These models, taking account of balance between good performance and accessibility of predictors, were subsequently validated and optimized for practicability.<span><sup>14</sup></span></p><p>Although these models have achieved promising results, several potential reasons limit their widespread implementation. First, risk prediction models developed from one population tend to overestimate or underestimate the CVD risk in other populations due to the heterogeneity in the patterns of CVD and risk factors.<span><sup>13</sup></span> Thus, these models need to be validated and recalibrated for better performance in the target population through future research. Second, the convenience of these models is crucial for risk assessment. Therefore, many teams have been working on improving the accessibility of these models using free web-based estimators such as the PCE models (tools.acc.org/ascvd-risk-estimator-plus), China-PAR equations (website [www.cvdrisk.com.cn], mobile apps, and WeChat applets). It is urgently required to incorporate these tools into electronic platforms in hospitals, community health centers, and the Centers for Disease Control and Prevention, and convey the automatically estimated cardiovascular risk to the potential benefit of interventions through lifestyle changes and/or therapeutic approaches by physicians and health providers. Moreover, user-friendly tools can facilitate self-assessment and self-management by the general public to raise awareness of the importance of maintaining a healthy lifestyle, planning individualized intervention strategies, and can further improve the accessibility and equality of health care. Third, the greatest challenge is not the models with better performance but government policies to encourage the implementation of the risk assessment and management. Currently, guidelines on the assessment and management of cardiovascular risk have been released in many countries to be easily and readily practiced in clinical or primary care settings.<span><sup>2, 3, 15</sup></span> Policies are urgently needed to implement guidelines on cardiovascular risk assessment and risk factor management, promote individualized prevention and treatment of CVD, and further reduce disease burden.</p><p>All risk assessment models, when applied to specific subgroups, might carry a risk misjudgment and further affect intervention and treatment strategies. Therefore, the American College of Cardiology/American Heart Association Guidelines introduced the novel concept of risk-enhancing factors as a supplement to risk models, such as metabolic syndrome, chronic kidney disease, chronic inflammatory conditions, history of premature menopause, and lipids/biomarkers.<span><sup>2</sup></span> These risk-enhancing factors can effectively improve the estimation of CVD risk and guide the implementation of preventive measures, especially in populations at borderline or intermediate cardiovascular risk. This finding emphasizes that risk-enhancing factors may affect the threshold for statin initiation or intensification. For example, the presence of risk-enhancing factors in individuals with a borderline risk may justify the initiation of moderate-intensity statin therapy. Additionally, the coronary artery calcium score should also be considered to optimize treatment decisions for these patients if risk-based decisions remain uncertain. Compared to traditional risk factors, risk-enhancing factors, such as coronary artery calcium, may not be available in all settings because their assessment may be expensive or even cause unnecessary radiation exposure. Moreover, some of them are not modifiable treatment targets but are simply markers of biological processes. Therefore, further evidence for their reclassification and cost-effectiveness is required.</p><p>Genetic factors, beyond traditional risk factors, also contribute to the vulnerability to CVD. Genome-wide association studies (GWASs) have identified hundreds of loci associated with CVD or related traits. By incorporating common genetic variants from GWASs to quantify genetic risk, the polygenic risk score (PRS) offers the opportunity to refine risk earlier in life, when few individuals express risk factors that exceed treatment thresholds. Contemporary PRS has broadened to include millions of variants using advanced statistical methods, displaying power in risk prediction.<span><sup>16</sup></span> The majority of PRSs have been derived and optimized using European GWASs. However, genetic heterogeneity across ancestry groups may influence the effect sizes of variants, leading to poor generalizability of these PRSs to other ancestry groups. Subsequently, PRSs for non-Europeans were developed. For example, PRSs of coronary artery disease and stroke in East Asians have been constructed using more than 500 genetic variants for CVD or related traits, showing good performance in the Chinese population.<span><sup>17-19</sup></span></p><p>The PRS plays an important role in the prevention of CVD and can stratify individuals into different trajectories of the CVD risk and indicate great potential for identifying high-risk individuals for targeted intervention. For example, polygenic risk determines the patterns of blood lipid changes, and individuals at high polygenic risk show the greatest annual changes toward unfavorable lipid profiles and require intensive lifestyle intervention.<span><sup>20</sup></span> Furthermore, adherence to cardiovascular health metrics could mitigate the genetic risk, and individuals with high genetic susceptibility would gain greater lifetime risk reductions.<span><sup>21, 22</sup></span> Thus, the PRS can be used to identify target populations and guide early lifestyle management to alleviate or even reverse their risks from a high genetic background. Moreover, incorporating the polygenic risk into conventional cardiovascular risk could further refine the risk stratification for CVD within each clinical risk stratum and provide useful risk stratification recommendations for identifying patients who should be initiated or administered intensive lifestyle changes and/or drug treatments.<span><sup>17</sup></span> Therefore, the PRS is a pragmatic tool in clinical practice for identifying high-risk individuals, guiding lifestyle interventions, and implementing precision preventive measures. However, more clinical trials and health economic evaluations are required to support the incorporation of PRS into existing CVD guideline-based prevention models and to determine the extent to which lifestyle improvements could reduce the polygenic risk of CVD. In addition, we need to identify the optimal cut-off for high genetic risk instead of directly using the highest quintile, as reported in several studies.</p><p>Increasing evidence supports the measurement of various omics levels to improve the risk prediction and identify the development of CVD.<span><sup>23</sup></span> These potential biomarkers have pro-inflammatory or proatherogenic effects and represent mechanistic relationships between clinical risk factors and CVD. Based on new proteomic technologies, novel protein biomarkers of CVD have been discovered, such as albumin, immunoglobulins, hemostatic factors, natriuretic peptides, interleukins, troponin, and creatine kinase.<span><sup>24</sup></span> Subsequently, proteome-based scores have been constructed and show better accuracy than conventional risk scores.<span><sup>25</sup></span> Small molecule metabolites, such as amino acids, lipids, and by-products of metabolism, can reflect multi-parametric host responses to external exposures. They may explain some of the interindividual variability in the associations of CVD with traditional risk factors and provide potential information for cardiovascular risk assessment.<span><sup>23</sup></span> In addition, other omics biomarkers, such as epigenetics, transcriptomics, and gut microbiome, can also help provide a longitudinal snapshot of individuals health status and enable more precise risk prediction and treatment approaches.<span><sup>23</sup></span> Although multi-omics biomarkers are promising, future investigation is warranted to better evaluate their role in CVD risk assessment and determine the cost-effectiveness and availability of the integration of these biomarkers into CVD primary prevention.</p><p>ML, a branch of artificial intelligence, can improve the accuracy of CVD risk prediction and help translate big data into clinical decision-making. ML has been used in assessing the cardiovascular risk and has outperformed conventional risk models.<span><sup>26</sup></span> Furthermore, the ML-driven incorporation of data from omics is promising for risk prediction.<span><sup>27</sup></span> Performing personalized risk prediction with ML could tailor better therapy for patients in urgent need of optimized care. However, ML is not the master key for every problem in the medical sciences. ML models are limited by the quality and magnitude of the data used to train them. Adding variables to models can cause noise owing to measurement methods and errors. Thus, more effort should be focused on validating the established ML models rather than developing new approaches.</p><p>Cardiovascular risk assessment is the foundation of CVD prevention efforts, while being an important stepping stone toward precision prevention. It is crucial to improve the accessibility of risk assessments using the Internet or smartphones, facilitate precision prevention by incorporating them into electronic health record platforms, and develop effective policies for their widespread implementation. Incremental improvements in risk assessment can be achieved through risk-enhancing factors, genetics, proteomics, metabolomics, and ML-driven data mining. However, their cost-effectiveness and availability should be evaluated in future studies.</p><p>Jianxin Li and Xiangfeng Lu drafted and revised this manuscript. All authors read and edited the manuscript.</p><p>The authors declare no conflict of interest. Professor Xiangfeng Lu is a member of Chronic Diseases and Translational Medicine editorial board and is not involved in the peer review and decision process of this article.</p><p>None.</p>","PeriodicalId":32096,"journal":{"name":"Chronic Diseases and Translational Medicine","volume":"9 4","pages":"273-276"},"PeriodicalIF":0.0000,"publicationDate":"2023-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Chronic Diseases and Translational Medicine","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/cdt3.90","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"Medicine","Score":null,"Total":0}
引用次数: 0

Abstract

Cardiovascular disease (CVD) is the most common noncommunicable disease and the leading cause of death globally.1 It has resulted in enormous economic and social burdens, while posing a great challenge for the prevention and control of CVD worldwide, especially in China. Assessment and management of cardiovascular risk is the foundation of CVD prevention, and is strongly recommended by guidelines.2-4 Additionally, it can help screen the target population who would benefit most from the lower-cost intervention, while informing them the cardiovascular risk, which will help in promoting self-management. It can also guide doctors in making logical management decisions, and implement precision prevention and treatment strategies to reduce the CVD burden.2, 4 Therefore, it is a key approach in achieving the goals of “Good Health and Well-being” in the United Nations and “Healthy China 2030” in China. Here, we briefly highlight several advances in cardiovascular risk assessments.

The Framingham Heart Study introduced the term “risk factor” in 1961, and identified a series of risk factors of CVD subsequently, such as cholesterol, blood pressure, glucose, and obesity.5 By integrating multiple conventional risk factors, a general cardiovascular risk instrument was further developed to assist in identifying and treating individuals at high risk.6 Since the concept of cardiovascular risk assessment and stratification was adopted by the third Adult Treatment Panel of the National Cholesterol Education Program in 2001, it has led to the development of effective treatment and preventive strategies in clinical practice.

A systematic approach to cardiovascular risk assessment includes the collection of information to calculate the cardiovascular risk, identification of the target high-risk population, and implementation of individual management according to the risk level. Therefore, risk-prediction models are major components of risk-based CVD prevention and control efforts. Several cardiovascular risk models have been developed using conventional risk factors to assist in clinical practice, such as the Reynolds Risk Score7, 8 and the Pooled Cohort Equations (PCE)9 in the United States, the QRISK in the United Kingdom,10 the ASSIGN Score in Scotland,11 the Systematic Coronary Risk Evaluation (SCORE) model in Europe,12 and the Prediction for Atherosclerotic CVD Risk in China (China-PAR) equations.13 In addition, World Health Organization has derived the risk prediction charts for 21 Global Burden of Disease regions to facilitate the risk-based CVD prevention in low- and middle-income countries.4 These models, taking account of balance between good performance and accessibility of predictors, were subsequently validated and optimized for practicability.14

Although these models have achieved promising results, several potential reasons limit their widespread implementation. First, risk prediction models developed from one population tend to overestimate or underestimate the CVD risk in other populations due to the heterogeneity in the patterns of CVD and risk factors.13 Thus, these models need to be validated and recalibrated for better performance in the target population through future research. Second, the convenience of these models is crucial for risk assessment. Therefore, many teams have been working on improving the accessibility of these models using free web-based estimators such as the PCE models (tools.acc.org/ascvd-risk-estimator-plus), China-PAR equations (website [www.cvdrisk.com.cn], mobile apps, and WeChat applets). It is urgently required to incorporate these tools into electronic platforms in hospitals, community health centers, and the Centers for Disease Control and Prevention, and convey the automatically estimated cardiovascular risk to the potential benefit of interventions through lifestyle changes and/or therapeutic approaches by physicians and health providers. Moreover, user-friendly tools can facilitate self-assessment and self-management by the general public to raise awareness of the importance of maintaining a healthy lifestyle, planning individualized intervention strategies, and can further improve the accessibility and equality of health care. Third, the greatest challenge is not the models with better performance but government policies to encourage the implementation of the risk assessment and management. Currently, guidelines on the assessment and management of cardiovascular risk have been released in many countries to be easily and readily practiced in clinical or primary care settings.2, 3, 15 Policies are urgently needed to implement guidelines on cardiovascular risk assessment and risk factor management, promote individualized prevention and treatment of CVD, and further reduce disease burden.

All risk assessment models, when applied to specific subgroups, might carry a risk misjudgment and further affect intervention and treatment strategies. Therefore, the American College of Cardiology/American Heart Association Guidelines introduced the novel concept of risk-enhancing factors as a supplement to risk models, such as metabolic syndrome, chronic kidney disease, chronic inflammatory conditions, history of premature menopause, and lipids/biomarkers.2 These risk-enhancing factors can effectively improve the estimation of CVD risk and guide the implementation of preventive measures, especially in populations at borderline or intermediate cardiovascular risk. This finding emphasizes that risk-enhancing factors may affect the threshold for statin initiation or intensification. For example, the presence of risk-enhancing factors in individuals with a borderline risk may justify the initiation of moderate-intensity statin therapy. Additionally, the coronary artery calcium score should also be considered to optimize treatment decisions for these patients if risk-based decisions remain uncertain. Compared to traditional risk factors, risk-enhancing factors, such as coronary artery calcium, may not be available in all settings because their assessment may be expensive or even cause unnecessary radiation exposure. Moreover, some of them are not modifiable treatment targets but are simply markers of biological processes. Therefore, further evidence for their reclassification and cost-effectiveness is required.

Genetic factors, beyond traditional risk factors, also contribute to the vulnerability to CVD. Genome-wide association studies (GWASs) have identified hundreds of loci associated with CVD or related traits. By incorporating common genetic variants from GWASs to quantify genetic risk, the polygenic risk score (PRS) offers the opportunity to refine risk earlier in life, when few individuals express risk factors that exceed treatment thresholds. Contemporary PRS has broadened to include millions of variants using advanced statistical methods, displaying power in risk prediction.16 The majority of PRSs have been derived and optimized using European GWASs. However, genetic heterogeneity across ancestry groups may influence the effect sizes of variants, leading to poor generalizability of these PRSs to other ancestry groups. Subsequently, PRSs for non-Europeans were developed. For example, PRSs of coronary artery disease and stroke in East Asians have been constructed using more than 500 genetic variants for CVD or related traits, showing good performance in the Chinese population.17-19

The PRS plays an important role in the prevention of CVD and can stratify individuals into different trajectories of the CVD risk and indicate great potential for identifying high-risk individuals for targeted intervention. For example, polygenic risk determines the patterns of blood lipid changes, and individuals at high polygenic risk show the greatest annual changes toward unfavorable lipid profiles and require intensive lifestyle intervention.20 Furthermore, adherence to cardiovascular health metrics could mitigate the genetic risk, and individuals with high genetic susceptibility would gain greater lifetime risk reductions.21, 22 Thus, the PRS can be used to identify target populations and guide early lifestyle management to alleviate or even reverse their risks from a high genetic background. Moreover, incorporating the polygenic risk into conventional cardiovascular risk could further refine the risk stratification for CVD within each clinical risk stratum and provide useful risk stratification recommendations for identifying patients who should be initiated or administered intensive lifestyle changes and/or drug treatments.17 Therefore, the PRS is a pragmatic tool in clinical practice for identifying high-risk individuals, guiding lifestyle interventions, and implementing precision preventive measures. However, more clinical trials and health economic evaluations are required to support the incorporation of PRS into existing CVD guideline-based prevention models and to determine the extent to which lifestyle improvements could reduce the polygenic risk of CVD. In addition, we need to identify the optimal cut-off for high genetic risk instead of directly using the highest quintile, as reported in several studies.

Increasing evidence supports the measurement of various omics levels to improve the risk prediction and identify the development of CVD.23 These potential biomarkers have pro-inflammatory or proatherogenic effects and represent mechanistic relationships between clinical risk factors and CVD. Based on new proteomic technologies, novel protein biomarkers of CVD have been discovered, such as albumin, immunoglobulins, hemostatic factors, natriuretic peptides, interleukins, troponin, and creatine kinase.24 Subsequently, proteome-based scores have been constructed and show better accuracy than conventional risk scores.25 Small molecule metabolites, such as amino acids, lipids, and by-products of metabolism, can reflect multi-parametric host responses to external exposures. They may explain some of the interindividual variability in the associations of CVD with traditional risk factors and provide potential information for cardiovascular risk assessment.23 In addition, other omics biomarkers, such as epigenetics, transcriptomics, and gut microbiome, can also help provide a longitudinal snapshot of individuals health status and enable more precise risk prediction and treatment approaches.23 Although multi-omics biomarkers are promising, future investigation is warranted to better evaluate their role in CVD risk assessment and determine the cost-effectiveness and availability of the integration of these biomarkers into CVD primary prevention.

ML, a branch of artificial intelligence, can improve the accuracy of CVD risk prediction and help translate big data into clinical decision-making. ML has been used in assessing the cardiovascular risk and has outperformed conventional risk models.26 Furthermore, the ML-driven incorporation of data from omics is promising for risk prediction.27 Performing personalized risk prediction with ML could tailor better therapy for patients in urgent need of optimized care. However, ML is not the master key for every problem in the medical sciences. ML models are limited by the quality and magnitude of the data used to train them. Adding variables to models can cause noise owing to measurement methods and errors. Thus, more effort should be focused on validating the established ML models rather than developing new approaches.

Cardiovascular risk assessment is the foundation of CVD prevention efforts, while being an important stepping stone toward precision prevention. It is crucial to improve the accessibility of risk assessments using the Internet or smartphones, facilitate precision prevention by incorporating them into electronic health record platforms, and develop effective policies for their widespread implementation. Incremental improvements in risk assessment can be achieved through risk-enhancing factors, genetics, proteomics, metabolomics, and ML-driven data mining. However, their cost-effectiveness and availability should be evaluated in future studies.

Jianxin Li and Xiangfeng Lu drafted and revised this manuscript. All authors read and edited the manuscript.

The authors declare no conflict of interest. Professor Xiangfeng Lu is a member of Chronic Diseases and Translational Medicine editorial board and is not involved in the peer review and decision process of this article.

None.

心血管风险评估:精准预防的关键途径
小分子代谢物,如氨基酸、脂质和代谢副产物,可以反映宿主对外界暴露的多参数反应。它们可以解释心血管疾病与传统危险因素之间的个体差异,并为心血管风险评估提供潜在信息此外,其他组学生物标志物,如表观遗传学、转录组学和肠道微生物组,也可以帮助提供个体健康状况的纵向快照,并实现更精确的风险预测和治疗方法虽然多组学生物标志物很有前景,但未来的研究需要更好地评估它们在心血管疾病风险评估中的作用,并确定将这些生物标志物整合到心血管疾病一级预防中的成本效益和可用性。ML是人工智能的一个分支,可以提高心血管疾病风险预测的准确性,帮助将大数据转化为临床决策。ML已被用于评估心血管风险,并且优于传统的风险模型此外,机器学习驱动的组学数据整合在风险预测方面很有希望使用ML进行个性化风险预测可以为迫切需要优化护理的患者量身定制更好的治疗方案。然而,机器学习并不是解决医学科学中所有问题的万能钥匙。ML模型受到用于训练它们的数据的质量和数量的限制。在模型中加入变量会由于测量方法和误差而产生噪声。因此,更多的努力应该集中在验证已建立的机器学习模型上,而不是开发新的方法。心血管风险评估是心血管疾病预防工作的基础,也是实现精准预防的重要基石。至关重要的是要改善利用互联网或智能手机进行风险评估的可及性,通过将其纳入电子健康记录平台来促进精确预防,并制定有效的政策以广泛实施风险评估。风险评估的增量改进可以通过风险增强因素、遗传学、蛋白质组学、代谢组学和ml驱动的数据挖掘来实现。但是,它们的成本效益和可得性应在今后的研究中加以评价。李建新、卢祥峰起草并修改了本稿。所有作者都阅读并编辑了手稿。作者声明无利益冲突。卢祥峰教授为《慢性疾病与转化医学》编委会成员,未参与本文的同行评议和决策过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
6.70
自引率
0.00%
发文量
195
审稿时长
35 weeks
期刊介绍: This journal aims to promote progress from basic research to clinical practice and to provide a forum for communication among basic, translational, and clinical research practitioners and physicians from all relevant disciplines. Chronic diseases such as cardiovascular diseases, cancer, diabetes, stroke, chronic respiratory diseases (such as asthma and COPD), chronic kidney diseases, and related translational research. Topics of interest for Chronic Diseases and Translational Medicine include Research and commentary on models of chronic diseases with significant implications for disease diagnosis and treatment Investigative studies of human biology with an emphasis on disease Perspectives and reviews on research topics that discuss the implications of findings from the viewpoints of basic science and clinical practic.
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