A How-To Guide for Promoting Diversity and Inclusion in Biomedical Engineering.

To accelerate the development of an inclusive culture in biomedical engineering (BME), we must accept complexity, seek to understand our own privilege, speak out about diversity, learn the difference between intent and impact, accept our mistakes, and learn how to engage in difficult conversations. In turn, we will be rewarded by the ideas, designs, devices and discoveries of a new generation of problem solvers and thought leaders who bring diverse experiences and perspectives.

Estrogen Preserves Pulsatile Pulmonary Arterial Hemodynamics in Pulmonary Arterial Hypertension.

Pulmonary arterial hypertension (PAH) is caused by extensive pulmonary vascular remodeling that increases right ventricular (RV) afterload and leads to RV failure. PAH predominantly affects women; paradoxically, female PAH patients have better outcomes than men. The roles of estrogen in PAH remain controversial, which is referred to as "the estrogen paradox".

Cardiac tissue structure, properties, and performance: a materials science perspective.

From an engineering perspective, many forms of heart disease can be thought of as a reduction in biomaterial performance, in which the biomaterial is the tissue comprising the ventricular wall. In materials science, the structure and properties of a material are recognized to be interconnected with performance. In addition, for most measurements of structure, properties, and performance, some processing is required.

Methods for measuring right ventricular function and hemodynamic coupling with the pulmonary vasculature.

The right ventricle (RV) is a pulsatile pump, the efficiency of which depends on proper hemodynamic coupling with the compliant pulmonary circulation. The RV and pulmonary circulation exhibit structural and functional differences with the more extensively investigated left ventricle (LV) and systemic circulation. In light of these differences, metrics of LV function and efficiency of coupling to the systemic circulation cannot be used without modification to characterize RV function and efficiency of coupling to the pulmonary circulation.

The effects of vasoactivity and hypoxic pulmonary hypertension on extralobar pulmonary artery biomechanics.

Loss of large artery compliance is an emerging novel predictor of cardiovascular mortality. Hypoxia-induced pulmonary hypertension (HPH) has been shown to decrease extralobar pulmonary artery (PA) compliance in the absence of smooth muscle cell (SMC) tone and to increase SMC tone in peripheral PAs. We sought to determine the impact of HPH on extralobar PA tone and the impact of SMC activation on extralobar PA biomechanics.

Pulmonary vascular remodeling in isolated mouse lungs: effects on pulsatile pressure-flow relationships.

Chronic hypoxia causes pulmonary vasoconstriction and pulmonary hypertension, which lead to pulmonary vascular remodeling and right ventricular hypertrophy. To determine the effects of hypoxia-induced pulmonary vascular remodeling on pulmonary vascular impedance, which is the right ventricular afterload, we exposed C57BL6 mice to 0 (control), 10 and 15 days of hypobaric hypoxia (n=6, each) and measured pulmonary vascular resistance (PVR) and impedance ex vivo. Chronic hypoxia led to increased pulmonary artery pressures for flow rates between 1 and 5ml/min (P<0.

The mechanobiology of pulmonary vascular remodeling in the congenital absence of eNOS.

Primary pulmonary hypertension is a rare but deadly disease. Lungs extracted from PPH patients are deficient in endothelial nitric oxide synthase (eNOS), making the eNOS-null mouse a potentially useful model of the disease. To better understand the progression of pulmonary vascular remodeling in the congenital absence of eNOS, we induced pulmonary hypertension in eNOS-null mice using hypobaric hypoxia, and then quantified large artery structure and function in contralateral vessels.

Measurements of mouse pulmonary artery biomechanics.

Background: Robust techniques for characterizing the biomechanical properties of mouse pulmonary arteries will permit exciting gene-level hypotheses regarding pulmonary vascular disease to be tested in genetically engineered animals. In this paper, we present the first measurements of the biomechanical properties of mouse pulmonary arteries.

Method Of Approach: In an isolated vessel perfusion system, transmural pressure, internal diameter and wall thickness were measured during inflation and deflation of mouse pulmonary arteries over low (5-40 mmHg) and high (10-120 mmHg) pressure ranges representing physiological pressures in the pulmonary and systemic circulations, respectively.