Cross-sectional evaluation of cardiovascular biological age using point-of-care ultrasound

Biological age, distinct from chronological age, is increasingly recognized as a more accurate indicator of morbidity, mortality, and physiological resilience. It captures interindividual variation in ageing trajectories shaped by genetic, behavioural, and environmental factors, and often surpasses chronological age in predicting health outcomes.^1–3 Diverse biological age clocks—based on epigenetic, haematological, metabolic, and imaging modalities—have demonstrated varying utility in forecasting disease risk and lifespan.^4–7 Among these, cardiovascular ageing clocks have emerged as particularly compelling, given the central role of cardiovascular integrity in ageing biology and its tight linkage to systemic metabolic health.^8,9

Existing modalities for cardiovascular age estimation, however, face several limitations. Conventional echocardiography, though highly informative, is time-intensive, operator-dependent, and not easily scalable. In contrast, point-of-care ultrasound (POCUS) has transformed bedside evaluation by offering a rapid, non-invasive window into cardiovascular function, particularly in acute care settings.^10–13 Yet POCUS alone suffers from interpretative variability and requires considerable training, limiting its application for standardized biological ageing assessment.^10,14

Recent advances in artificial intelligence (AI) have begun to bridge this gap. AI-enhanced interpretation of cardiac ultrasound images has shown high diagnostic accuracy for detecting subclinical cardiac dysfunction and stratifying cardiovascular risk in a reproducible, operator-independent manner.^15–19 Building on these foundations, cardiovascular biological age derived from AI-powered POCUS now offers an accessible, scalable, and physiologically relevant biomarker. Critically, recent work suggests that a higher cardiovascular biological age particularly when discordant from chronological age predicts adverse clinical outcomes, including excess cardiovascular mortality.²⁰

This study introduces and evaluates an AI-based, handheld ultrasound-derived cardiovascular age clock. We compare this modality against two other validated biological ageing tools: A haematological ageing clock (blood-based), and a neural network-based electrocardiographic (ECG) ageing clock. By leveraging comprehensive clinical and metabolic profiling, we examine the interrelationships, divergences, and clinical correlates of each clock’s outputs.

Our central aim is to assess whether AI-augmented cardiovascular biological age captured at the bedside in under 5 min can serve not only as a feasible and scalable tool but also as a distinct and clinically meaningful indicator of subclinical cardiometabolic stress. We explore the degree to which this clock is associated with high-risk phenotypes, its correlation with traditional risk markers, and its potential role in risk stratification strategies. This work contributes to the growing body of literature advocating for biologically anchored, AI-driven tools to guide early detection and intervention in age-related disease

The final cohort comprised 243 participants (median age: 62 years, IQR: 56–68), with 131 (54%) women. Participants were stratified into quintiles according to the bias-corrected delta between US-based CV biological age and chronological age, where Quintile 1 represented biologically ‘super agers’ and Quintile 5 represented ‘accelerated agers’. Details of the age-bias correction procedures are provided in Appendix Supplementary material online, Figure S1. The full distribution of clinical and demographic characteristics across quintiles is provided in Supplementary material online, AppendixTable S1. On focused POCUS examination, most participants showed no echocardiographic findings warranting clinical referral. In quintile 5, 45/49 (91.8%) had no abnormal findings compared with 183/194 (94.3%) in quintiles 1–4, with no significant difference between groups (χ²(1) = 0.42, P = 0.517).

Table 1 compares baseline characteristics of accelerated agers (Q5, n = 48) with all remaining participants (Q1–Q4, n = 195). Following bias correction, the two groups did not differ significantly in chronological age (60.9 ± 6.6 vs. 62.4 ± 8.7 years, P = 0.20). Despite similar chronological age, accelerated agers demonstrated a significantly less favourable cardiometabolic profile. They had higher diastolic blood pressure (79.9 ± 8.3 vs. 75.8 ± 8.4 mmHg, P = 0.004), BMI (27.9 ± 3.6 vs. 25.1 ± 3.8 kg/m², P < 0.001), waist circumference (97.6 ± 9.3 vs. 89.5 ± 11.4 cm, P < 0.001), triglycerides (117.3 ± 78.7 vs. 91.3 ± 49.0 mg/dL, P = 0.03), and more than double the prevalence of metabolic syndrome (23% vs. 10%, P = 0.03). Conversely, they had lower HDL cholesterol (57.0 ± 13.1 vs. 64.0 ± 15.6 mg/dL, P = 0.002). No significant differences were observed in systolic blood pressure, total cholesterol, LDL cholesterol, apolipoprotein B levels, C-reactive protein, smoking status, physical activity, body fat percentage, or prior CVD history.

There was no statistical difference in the prevalence of reduced ejection fraction (EF < 55%) between accelerated agers (8.3%) and all other participants (9.6%). No statistical differences were observed between the groups in other echocardiographic features measured; left atrial area, right atrial area, pericardial effusion, right ventricular function, aortic root diameter, left ventricular end diastolic diameter, right ventricular fractional area change.

These findings indicate that membership in the top quintile of US-based CV biological ageing captures individuals who are metabolically older, highlighting the clock’s association with prevalent cardiometabolic disease.

This study provides novel evidence for the potential clinical utility of an ultrasound-based CV biological age clock derived from focused cardiac point-of-care ultrasound (POCUS). US-based CV clock is associated with adverse cardiometabolic profiles, whereas blood-based and ECG-derived clocks showed weaker or inconsistent relationships. Most participants had no echocardiographic findings that would warrant clinical referral, yet substantial variability in US biological age was detected, suggesting its ability to capture physiological differences not reflected in routine focused POCUS interpretation.

Accelerated agers defined by the US clock exhibited consistently worse cardiometabolic traits, including higher BMI, greater waist circumference, elevated diastolic blood pressure, higher triglycerides, higher prevalence of metabolic syndrome and lower HDL cholesterol. These associations were observed despite similar chronological age distributions between accelerated and non-accelerated groups, indicating that the US-based CV clock captures biological heterogeneity relevant to cardiometabolic health beyond age alone. A single US-based CV biological age identify patients with known cardiometabolic risk factors, such as metabolic syndrome, hypertension and dyslipidaemia. These results are consistent with prior work demonstrating increased long-term mortality among US-based CV accelerated agers using the same tool.²⁰

Beyond quintile stratification, we identified a practical clinical threshold: participants whose US biological age exceeded their chronological age by ≥2 years had significantly higher odds of metabolic syndrome (OR = 2.34), even after adjustment for chronological age and sex. This cut-off provides an interpretable reference within the current cohort, although external validation is required before broader application. These findings suggest that US-based biological age reflects meaningful variation in cardiometabolic status rather than a purely statistical construct.

Although all three clocks correlated strongly with chronological age, concordance in identifying accelerated agers was weak (Cohen’s κ <0.20). This dissociation highlights that each clock captures distinct aspects of biological ageing. The blood clock reflects systemic and lipid-related processes, while the US clock appears to integrate structural and functional cardiac adaptations linked to metabolic stress. ECG-derived age demonstrated moderate associations. Thus, the clocks are complementary rather than redundant, and their combined use may enhance individualized risk assessment.

A key strength of the US clock is its dual role in a single brief examination. Every POCUS scan already provides standard echocardiographic information ventricular size and function, valvular integrity, ejection fraction, and stroke volume that guides routine clinical care. The same images, analysed by AI, simultaneously yield an estimate of US biological age. This additional layer of information requires no extra acquisition or laboratory testing and may provide complementary characterization of cardiometabolic phenotype within the context of a cross-sectional assessment, particularly in settings where comprehensive metabolic evaluation is not routinely available.

Several limitations must be acknowledged. First, as the study is cross-sectional, age-delta reflects associations with prevalent cardiometabolic traits rather than prediction of incident outcomes. Accordingly, the findings do not establish impact on clinical outcomes or preventive benefit, and longitudinal follow-up will be required to determine prognostic value and incremental utility beyond standard clinical evaluation. Second, the population consisted of health-conscious, self-referred volunteers, limiting generalizability. Broader, more diverse cohorts are needed to validate findings. Third, while feasibility was high overall (94%), image quality excluded a minority of scans. Fourth, reproducibility (test–retest reliability) was not assessed because repeat scanning was not performed; this should be evaluated in future work. Finally, although a clinically relevant ΔAge threshold was identified, external validation in independent cohorts is essential before considering broader clinical implementation.