8 research outputs found
A cross-sectional analysis of perinatal depressive symptoms among Punjabi-speaking women: are they at risk?
BACKGROUND: Depression is the leading cause of disability for childbearing women. We examined three specific research questions among Punjabi-speaking women residing in the Fraser Health Authority: 1) What are the prevalence rates of prenatal depressive symptoms? 2) Do Punjabi-speaking women have a higher likelihood of reporting depressive symptoms compared to English-speaking women after controlling for age, level of education and financial worries, and 3) Given the same level of exposure to level of education and financial worries, do Punjabi-speaking women have the same likelihood of reporting depressive symptoms? METHODS: Data originated from the Fraser Health Authority prenatal registration database consisting of pregnant women (n = 9684) who completed a prenatal registration form between June 2009 and August 2010; 9.1 % indicated speaking Punjabi. The Whooley Depression Screen measured depressive symptoms. Chi-square tests and logistic multiple regression were used to examine the rates of reporting depressive symptoms among Punjabi-speaking women compared to English-speaking women. RESULTS: Punjabi-speaking women are at a higher risk for perinatal depressive symptoms. Women needing an interpreter were more likely to report prenatal depressive symptoms compared to English-speaking women. All registrants who reported financial worries had four and a half times the odds of reporting depressive symptoms. The impact of financial worries was significantly greater in the English-speaking women compared to the Punjabi-speaking women needing an interpreter. CONCLUSION: Using an established screening device, Punjabi-speaking women were found to be at higher risk for prenatal depressive symptoms
Reactive oxygen species and cerebrovascular diseases
In the normal physiologic state, reactive oxygen species (ROS) generation is intentional and important for the functioning of cerebral and systemic circulations. Furthermore, emerging evidence indicates that cerebral arteries generate higher levels of ROS than arteries outside of the brain in the normal physiologic state. As such, it has been proposed that ROS may play a more prominent role in the physiologic regulation of cerebral arteries. There are numerous potential enzymatic sources of ROS in the cerebral vasculature; however, increasing evidence indicates that the family of NADPH oxidases is a major source. Aberrant redox signaling or oxidative stress in the cerebral circulation, usually as a result of excessive production of ROS and reactive nitrogen species (RNS), is a common feature in diverse models of cardiovascular risk factors (e.g., hypertension, hypercholesterolemia) and cerebrovascular disease. Furthermore, oxidative stress is now believed to be an underlying cause of cerebrovascular dysfunction and damage associated with these disease states. In this chapter, we summarize the effects and potential roles of ROS/RNS in modulating cerebral artery function in the normal physiologic state, with a particular focus on their roles in modulating cerebrovascular tone. Furthermore, we will highlight current evidence for the involvement of ROS/RNS in cerebrovascular dysfunction associated with cardiovascular risk factors, stroke, and Alzheimer's disease
Hemodynamics: An Introduction
International audienceThe cardiovascular transport circuit is involved in both mass and heat transfer. It carries blood cells as well as oxygen and nutrients to cells of the body’s organs through the perfusing systemic arterial bed and wastes produced by working cells to their final destinations through draining veins. Blood flows throughout the body in the vasculature due to a pressure difference between the ventricular outlet and atrial inlet. Blood is propelled in the systemic and pulmonary circulation by the synchronized action of the left and right apposed cardiac pumps, respectively. Hemodynamics is related to the flow features in the heart and blood vessels, in normal and pathological conditions, in particular the pressure–flow relations and transport of substances by blood to given target organs. It can be required in therapy planning and optimization