Optimizing cerebrovascular endothelial health through shear stress modulation

Erika Iwamoto; Rintaro Sakamoto; Darren P Casey

doi:10.1113/EP092668

Back

Optimizing cerebrovascular endothelial health through shear stress modulation

Journal article

Open access

Peer reviewed

Optimizing cerebrovascular endothelial health through shear stress modulation

Erika Iwamoto, Rintaro Sakamoto and Darren P Casey

Experimental physiology

12/08/2025

DOI: 10.1113/EP092668

PMID: 41362012

Appears in UI Libraries Support Open Access

Files and links (1)

url

https://doi.org/10.1113/EP092668View

Published (Version of record) Open Access

Abstract

The endothelium plays a pivotal role in regulating cerebrovascular blood flow, and its dysfunction increases the risk of cerebrovascular disease. Endothelial shear stress, a primary mechanical stimulus for endothelial nitric oxide production, is a key modulator of vascular adaptation. In recent years, transient hypercapnia-induced flow-mediated dilation of the internal carotid artery (ICA-FMD) has emerged as a valuable in vivo approach for assessing cerebrovascular endothelial function in humans. This review first synthesizes methodological advances in ICA-FMD assessment, emphasizing the importance of transient carbon dioxide (CO ) inhalation, normalizing ICA-FMD to the shear stress, and consideration of unique ICA haemodynamics. Second, it consolidates mechanistic insights and conditions for improving ICA-FMD, elucidating effective and ineffective strategies. Intermittent hypoxia-induced increases in shear stress improve ICA dilatory response, underscoring the pivotal role of shear rate. Although ICA blood flow during exercise has been extensively studied, data on shear rate during exercise are limited. Moderate-intensity leg cycling that avoids hyperventilation and elevates end-tidal CO partial pressure increases ICA shear rate and augments post-exercise ICA-FMD, whereas higher-intensity exercise or small-muscle exercise fails to produce similar benefits. These observations suggest that a threshold shear stimulus may be required for post-exercise improvements in ICA-FMD. Future research should establish standardized methodologies, define the shear stimulus threshold, elucidate the time course of vascular adaptations, and extend investigations to populations at elevated cerebrovascular risk. Translating these mechanistic insights into clinical strategies has the potential to optimize cerebrovascular endothelial function and thereby contribute to the prevention of cerebrovascular diseases.

Exercise

endothelial function

cerebral artery

internal carotid artery

intermittent hypoxia

hypercapnia

UIOWA OA Agreement

Details

Title: Subtitle: Optimizing cerebrovascular endothelial health through shear stress modulation
Creators: Erika Iwamoto - Sapporo Medical University
Rintaro Sakamoto - National Institute of Advanced Industrial Science and Technology
Darren P Casey - University of Iowa
Resource Type: Journal article
Publication Details: Experimental physiology
DOI: 10.1113/EP092668
PMID: 41362012
NLM abbreviation: Exp Physiol
ISSN: 1469-445X
eISSN: 1469-445X
Publisher: Wiley
Grant note: 25K03021 / Japan Society for the Promotion of Science (JSPS)
Language: English
Electronic publication date: 12/08/2025
Academic Unit: Physical Therapy and Rehabilitation Science; Fraternal Order of Eagles Diabetes Research Center
Record Identifier: 9985090639402771

Metrics

2 Record Views