Obstructive sleep apnea (OSA) is defined as brief and repeated interruptions of breathing due to upper airway obstructive events during the sleep1; these recurrent interruptions could be complete (apneas) and/or partial (hypopneas), resulting in intermittent hypoxemia, autonomic fluctuation, and sleep fragmentation.2 The apnea-hypopnea index (AHI) quantifies the episodes of apnea (cessation of airflow for at least 10 seconds) and hypopnea (reduction in airflow by at least 30% for at least 10 seconds with decrease in blood oxygen saturation). When defined as an AHI > 5 events per hour of sleep, the prevalence of OSA in the United States is ∼15-30% in males and 10–15% in females; instead, if defined as AHI ≥5 events per hour plus symptoms or AHI ≥15 events per hour), the prevalence is approximately 15% in males and 5% in females.3 OSA is typical in adults; males, older, and obese individuals are at a higher risk.4 The prevalence of OSA may also be influenced by race: indeed, it is common in African-Americans, independent of body weight.5, 6 Patients with OSA have an increased incidence of hypertension, even when asymptomatic.7-9 Arterial stiffness is common in hypertension and is a sign of structural and functional alterations of the vascular wall, associated with organ damage.10, 11 On the other side of the coin, patients with resistant hypertension have a high prevalence of OSA.12, 13 Hence, hypertensive patients with arterial stiffness and OSA have many complications and adverse outcomes.14 Nonetheless, the complex relationship linking hypertension, arterial stiffness, and OSA is not fully clear (Figure 1). To elucidate this matter, Saeed and associates prospectively investigated a large population of 6408 participants with suspected OSA undergoing a standard respiratory polygraphy, and the results have been published in this issue of the Journal of Clinical Hypertension.15 The prevalence of hypertension was 70.8% in OSA patients (defined as AHI ≥15/h) and 46.7% in non-OSA controls (P < .0001). Hypertension and obesity were the most common modifiable cardiovascular risk factors among OSA patients; approximately one-fourth of OSA patients displayed an increased arterial stiffness, defined by a brachial pulse pressure (PP) ≥60 mmHg. Albeit in an unadjusted logistic regression model, OSA was associated with a 1.3-fold higher risk of having increased PP, in a multivariable-adjusted model, OSA did not retain its association with arterial stiffness, which was instead maintained by age, male sex, and history of hypertension. It is important to note that the Authors only used PP to quantify arterial stiffness and did not use PWV, generally considered the gold standard method; furthermore, the duration of antihypertensive treatment in the population was not known. OSA is associated with a marked increase in sympathetic activity during sleep, which influences heart rate and blood pressure.16 This augmented sympathetic activity in OSA patients is most likely a result of intermittent hypoxemia, hypercapnia, and sleep fragmentation.14, 17, 18 In a controlled trial, 318 patients with moderate-to-severe OSA were randomized to either sleep education (control arm) or continuous positive airway pressure (CPAP), or nocturnal supplemental oxygen, for a period of 12 weeks; CPAP was associated with a 2.8 mmHg greater reduction in mean arterial pressure compared to controls, whereas supplemental oxygen alone did not significantly reduce blood pressure.19 A recent large clinical trial conducted in 31 309 patients undergoing overnight polysomnography revealed that patients with more severe OSA as measured by the AHI are more likely to have incident venous thromboembolism; however, adjusted analyses suggest that this association is explained due to confounding by obesity.20 Indeed, OSA patients have been shown to have higher circulating levels of leptin compared to controls, and these levels are positively correlated with the AHI.21 Instead, the strong association between OSA and coronary and cerebral vascular disease appears to be independent of shared risk factors including adiposity.22 Hypertension is one of the main determinants of endothelial dysfunction, particularly in the aging population.23 Cognitive dysfunction is a well-known complication of hypertension and other cardiovascular diseases24, 25 and several reports have highlighted the relationships between arterial stiffness and cognition in hypertensive patients.26-28 Furthermore, OSA sleep-disordered breathing has been associated with an increased risk of cognitive impairment.17, 29 A recent study30 evidenced a significant correlation (r: 0.30; P: .002) between arterial stiffness and executive function-processing speed performance in patients with OSA and chronic obstructive pulmonary disease (COPD). Therefore, it should be interesting to investigate the relationship between arterial stiffness and cognitive dysfunction in hypertensive patients with OSA. OSA remains too often underdiagnosed and undertreated in cardiovascular practice, despite its high prevalence in patients with cardiovascular disease and the vulnerability of cardiac patients to OSA-related stressors. A recent scientific statement of the American Heart Association recommends screening for OSA in patients with resistant (or poorly controlled) hypertension, pulmonary hypertension, and recurrent atrial fibrillation after either cardioversion or ablation.2 The Santulli's Lab is supported in part by the National Institutes of Health (NIH: R01-HL146691, R01-HL159062, R01-DK123259, R01-DK033823, and T32-HL144456, to G.S.), by the Irma T. Hirschl and Monique Weill-Caulier Trusts (to G.S.), and by the Diabetes Action Research and Education Foundation (to G.S.); F.V. holds a postdoctoral fellowship from the American Heart Association (AHA-22POST995561). The authors have no competing interests.