Probing shear-stress-mediated cerebral vasodilatation in humans - it's a NO brainer.

Abstract

The burden of brain diseases (e.g. stroke, dementia, Alzheimer’s disease) is considerable and has grown substantially alongside the increased life expectancy of western industrialised nations. Disrupted cerebrovascular endothelial function contributes significantly to the pathogenesis and neurodegeneration of several of these conditions. The early identification of individuals with or at risk of cerebrovascular impairments, using tests with a robust mechanistic basis, may have clinical utility for guiding interventional strategies, thereby helping to ameliorate disease progression before it becomes firmly established. Some of the earliest measurements of cerebral blood flow in humans quantified the “striking and consistent” steady-state hyperaemic response to the inhalation of carbon dioxide (CO2) (5–7%) (Kety & Schmidt 1948), which is important for pH and thus neuronal homeostasis. Subsequently, the cerebrovascular response to a steady-state CO2 stimulus test has been reported to be diminished in several clinical conditions and has prognostic value (Juttukonda & Donahue 2019). In a recent issue of the Journal of Physiology, Hoiland and colleagues provided important new mechanistic insights into a novel test that potentially provides a targeted assessment of cerebrovascular endothelial function. A transient CO2 stimulus – provided by inspiring a CO2-enriched gas mixture to raise PETCO2 by +9 mmHg for 30 s – evokes an increase in shear stress within the internal carotid artery (ICA) that peaks at ∼20 s after CO2 onset and is followed by ICA vasodilatation at ∼80 s (Hoiland et al. 2017). Since this time course is akin to that observed in other conduit vessels during the flow-mediated dilatation test, the authors discounted any direct actions of CO2 and instead hypothesized that a shear-stress-mediated release of nitric oxide (NO) was responsible for the latent ICA vasodilatation. To explore this possibility, Hoiland et al. (2022) re-evaluated the ICA response to the transient CO2 stimulus both with a saline control and i.v. infusion of the non-selective NO synthase inhibitor, NG-monomethyl-l-arginine (l-NMMA, 5 mg/kg bolus and 50 μg/kg/ min maintenance dose). Notably, l-NMMA abolished the increase in the trans-cerebral release of nitrite (index of NO production) during the transient CO2 stimulus and reduced the increase in ICA vasodilatation (by ∼37%), while shear stress was not different between conditions. Such observations were interpreted as revealing the integral role of shear-stress-mediated endothelial NO release to the cerebrovascular response to a transient CO2 stimulus. In contrast, an NO synthasemechanismwas not observed to be obligatory for the cerebrovascular response to steady-state CO2 stimulus. Indeed, the magnitude of the ICA response, along with that of the vertebral artery (VA) and middle cerebral artery blood velocity (MCAv), to steady-state hypercapnia (5 min at +4.5 and +9 mmHg PaCO2 ) was not different in the l-NMMA and saline conditions. The observed failure of l-NMMA to diminish steady-state cerebrovascular CO2 reactivity is perhaps surprising given the available in vitro and in vivo evidence supporting the role of endothelial-derived NO in CO2/H+-mediated cerebral vasodilatation (Yoon et al. 2012). Indeed, in patients with cardiovascular risk factors, diminished steady-state cerebrovascular CO2 reactivity ( MCAv/ PETCO2 ) is reportedly associated with impaired peripheral vascular NO signalling (Lavi et al. 2006), while l-arginine infusion (a precursor of NO) restores the blunted steady-state cerebrovascular CO2 reactivity (Zimmermann & Haberl 2003). These discrepancies may relate to the differing primary outcome variables (ICA diameter vs. MCAv) and study cohorts, along with the redundancy in mechanisms controlling cerebral blood flow. Nevertheless, for investigators evaluating strategies by which the NO synthase-dependent pathway could be targeted to enhance cerebrovascular endothelial function (e.g. nutrition, physical activity), the transient CO2 test may provide superior specificity over traditional steady-state methods. Practical and scientific advantages of the transient CO2 over the steady-state approach include the shorter exposure perhaps more readily lending itself to use in higher-risk patients and limiting confounding side effects (e.g. hypercapniainduced sympathetic nervous system activation). While the technical set-up required to assess the cerebrovascular response to a transient CO2 stimulus is impressively sophisticated, it could pose a significant barrier to the wider adoption of this approach in both research and clinical settings. Irrespectively, the application of this technique in relevant patient groups (e.g. those at risk of, or with established, cerebrovascular complications) and the exploration of its prognostic utility is important, as is determining how its sensitivity/specificity compares to steady-state cerebrovascular CO2 reactivity. No doubt there will also be interest in describing how changing physiological conditions (e.g. heat, exercise, mental stress, hypoxia), both acutely and chronically, affect the cerebrovascular response to a transient CO2 stimulus in a variety of groups. In summary, Hoiland et al. (2022) utilize a cutting-edge experimental approach to provide valuable mechanistic insights into a novel modality for assessing cerebrovascular endothelial function. The demonstration that the shear-stress-mediated vasodilatation in an extracranial vessel (i.e. ICA) provoked by a transient CO2 stimulus is substantively dependent on NO synthase activity is valuable. Basic studies to elucidate other contributing vasoactive mediators (e.g. prostaglandins) and applied studies in relevant patient populations to quantify cerebrovascular endothelial function and assess the prognostic utility of this novel marker would be exciting future directions for exploration.