Michel R. Labrosse

Ottawa University

H-index: 26

North America-United States

About Michel R. Labrosse

Michel R. Labrosse, With an exceptional h-index of 26 and a recent h-index of 22 (since 2020), a distinguished researcher at Ottawa University, specializes in the field of Cardiovascular mechanics, aorta, aortic and mitral valves.

His recent articles reflect a diverse array of research interests and contributions to the field:

Programmable Melt Electrowriting to Engineer Soft Connective Tissues with Prescribed, Biomimetic, Biaxial Mechanical Properties

Glycosaminoglycans modulate compressive stiffness and circumferential residual stress in the porcine thoracic aorta

Investigation of the Heterogeneous Mechanical Properties of the Intact and GAG-depleted Thoracic Aortic Tree using Indentation

EFFECT OF GLYCOSAMINOGLYCANS ON OPENING ANGLE OF INTACT & CROSSLINKED AORTAS

Intramural Distributions of GAGs and Collagen vs. Opening Angle of the Intact Porcine Aortic Wall

The contribution of glycosaminoglycans/proteoglycans to aortic mechanics in health and disease: a critical review

Significant Fatigue Life Enhancement in Multiscale Doubly-Modified Fiber/Epoxy Nanocomposites with Graphene Nanoplatelets and Reduced-Graphene Oxide

Intramural Glycosaminoglycans Distribution vs. Residual Stress in Porcine Ascending Aorta: a Computational Study*

Michel R. Labrosse Information

University	Ottawa University
Position	Professor Department of Mechanical Engineering
Citations(all)	2725
Citations(since 2020)	1272
Cited By	2025
hIndex(all)	26
hIndex(since 2020)	22
i10Index(all)	41
i10Index(since 2020)	31
Email	Access Email
University Profile Page	Ottawa University
Google Scholar	View Google Scholar Profile

Michel R. Labrosse Skills & Research Interests

Cardiovascular mechanics

aorta

aortic and mitral valves

Top articles of Michel R. Labrosse

Title	Journal	Author(s)	Publication Date
Programmable Melt Electrowriting to Engineer Soft Connective Tissues with Prescribed, Biomimetic, Biaxial Mechanical Properties	Advanced Functional Materials	Bahram Mirani Sean O Mathew Neda Latifi Michel R Labrosse Brian G Amsden ...	2024/1
Glycosaminoglycans modulate compressive stiffness and circumferential residual stress in the porcine thoracic aorta	Acta Biomaterialia	Noor M Ghadie Michel R Labrosse Jean-Philippe St-Pierre	2023/10/15
Investigation of the Heterogeneous Mechanical Properties of the Intact and GAG-depleted Thoracic Aortic Tree using Indentation	CMBES Proceedings	Noor Ghadie Jean-Philippe St-Pierre Michel Labrosse	2023/5/14
EFFECT OF GLYCOSAMINOGLYCANS ON OPENING ANGLE OF INTACT & CROSSLINKED AORTAS	Canadian Journal of Cardiology	Noor Ghadie J St-Pierre M Labrosse	2022/10/1
Intramural Distributions of GAGs and Collagen vs. Opening Angle of the Intact Porcine Aortic Wall	Annals of Biomedical Engineering	Noor M Ghadie Jean-Philippe St-Pierre Michel R Labrosse	2022/2
The contribution of glycosaminoglycans/proteoglycans to aortic mechanics in health and disease: a critical review		Noor M Ghadie Jean-Philippe St-Pierre Michel R Labrosse	2021/4/19
Significant Fatigue Life Enhancement in Multiscale Doubly-Modified Fiber/Epoxy Nanocomposites with Graphene Nanoplatelets and Reduced-Graphene Oxide	Polymers	Mohammad Rafiee Somayeh Hosseini Rad Fred Nitzsche Laliberte. Jeremy Michel Labrosse	2020/9/18
Intramural Glycosaminoglycans Distribution vs. Residual Stress in Porcine Ascending Aorta: a Computational Study*		Noor Ghadie Jean-Philippe St-Pierre Michel R Labrosse	2020/7/20
A computational study on deformed bioprosthetic valve geometries: Clinically relevant valve performance metrics	Journal of biomechanical engineering	Reza Jafar Michel R Labrosse Jason D Weaver Stephen M Retta Changfu Wu ...	2020/1/1