The goal of this preliminary study is to learn if healthy older African American (AA) adults have a larger change in their kidney blood flow during exercise compared to White (W) adults. The main questions that this study aims to answer are: * Do healthy older AA adults have a larger decrease in kidney blood flow during exercise compared to W adults? * Do healthy older AA adults have a larger decrease in kidney blood flow during other types of stress compared to W adults? During one visit in the research lab, participants will: * Perform cycling exercise while lying down * Undergo a cold hand test * Perform a mental math test Completing this preliminary study will help researchers to understand more about why many AA adults have heart and kidney problems, so future research can study ways to reduce the number of AA adults who have these health issues.
Racial disparities exist in the development of high blood pressure and heart and kidney disease. Over the last 25 years, African American (AA) adults have had the greatest prevalence of high blood pressure compared to any other racial identity group in the United States. In 2015, \~100,000 AA adults died from heart disease, accounting for one-third of all deaths in this population. AA adults also have a 2-3-times higher lifetime risk for developing end-stage kidney disease compared to White (W) adults. Further, advanced age is one of the most significant risk factors for developing high blood pressure, heart disease, and kidney disease. In 2013-2014, \~29% of deaths of adults aged 65 years or older were caused by heart disease, the leading cause of death in this population. Elevated sympathetic nervous system activity is associated with increased incidence of heart and kidney disease. Physical activity, such as exercise, acutely increases sympathetic nervous system activity, notably directed towards the kidneys, resulting in reflex narrowing of small blood vessels inside the kidneys. This response reduces blood flow to the kidneys to deliver greater blood flow to the active skeletal muscles. Most of the research studies in this area have involved participant groups who were wholly or predominantly of W racial identity, with smaller proportions of individuals of other racial identities. This underrepresentation of non-W participants, including AA adults, has occurred despite the known health disparities such as the greater incidence of high blood pressure and heart disease and kidney disease experienced by these populations. A larger decrease in kidney blood flow during exercise has been observed in patients with heart failure and peripheral arterial disease compared to healthy adults. However, it is not known whether the decrease in kidney blood flow during exercise is larger in healthy older AA adults compared to other racial identity groups. Given the greater level of chronic psychological stress often experienced by AA adults due to systemic racism and social and environmental factors, the associated cumulative negative impact on cardiovascular health could underlie a physiological difference observed between AA and W adults. Therefore, it is hypothesized that healthy older AA adults will exhibit a larger decrease in kidney blood flow during exercise compared to W adults. This greater response in older AA adults could be a significant factor contributing to the higher rates of heart and kidney disease in this population given the negative effect that this larger response could have over time, highlighting the clinical significance of this area. The goal of this project is to collect preliminary data regarding the kidney blood flow response to exercise in healthy older AA compared to W adults. This will be achieved through the innovative use of Doppler ultrasound to noninvasively measure kidney blood flow in real time during cycling exercise in 6 healthy older AA adults and 6 healthy older W adults. The preliminary data collected in this project will be used to strengthen future proposals to secure external funding to complete this project on a larger scale. Findings from a larger-scale project will have important implications for developing preventative strategies to reduce the elevated risk of developing heart and kidney disease in the AA population.
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
12
Participants will lie in a semi-supine position with their feet attached to the pedals of a custom-arranged cycle ergometer. Participants' 40% heart rate reserve will be calculated, giving the target value to achieve during exercise based on appropriate resistance applied on the cycle ergometer, corresponding to a moderate exercise intensity. After a 5-minute resting baseline, participants will perform dynamic cycling exercise at steady state for up to 20 minutes. They will then stop exercising, and there will be a 5-minute recovery period. Beat-to-beat renal blood flow velocity (Doppler ultrasound), mean arterial blood pressure (finger photoplethysmographic cuff), and heart rate (electrocardiogram) will be recorded throughout. A rating of perceived exertion will be taken from participants during the last 30 seconds of steady-state cycling exercise.
Participants will lie in a semi-supine position, and after a 3-minute resting baseline, participants will have their hand immersed in ice water for 2 minutes. This cold pressor test represents the non-exercise, physical sympathetic stressor. Participants' hand will then be removed from the ice water, followed by a 3-minute recovery period. Beat-to-beat renal blood flow velocity (Doppler ultrasound), mean arterial blood pressure (finger photoplethysmographic cuff), and heart rate (electrocardiogram) will be recorded throughout. Ratings of hand pain and cold perception will be taken from participants during the last 30 seconds of the cold pressor test.
Participants will lie in a semi-supine position, and after a 3-minute resting baseline, participants will perform a mental arithmetic task for 5 minutes. This mental stress test represents the non-exercise, psychological sympathetic stressor. Participants will be instructed to subtract a given number from a randomly selected three-digit number and verbally state their answer and continue to do so for the duration of the test. Participants will be instructed to state their answers as quickly and accurately as possible. Participants will then stop the arithmetic task, and a 3-minute recovery period will follow. Beat-to-beat renal blood flow velocity (Doppler ultrasound), mean arterial blood pressure (finger photoplethysmographic cuff), and heart rate (electrocardiogram) will be recorded throughout. A rating of perceived stress will be taken from participants during the last 30 seconds of the mental stress test.
University of Massachusetts Boston
Boston, Massachusetts, United States
RECRUITINGChange in renal vascular resistance during acute exercise
For the acute exercise intervention, the percent change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in renal vascular resistance during cold pressor test
For the cold pressor test intervention, the percent change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in renal vascular resistance during mental stress test
For the mental stress test intervention, the percent change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in renal blood flow velocity during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in mean arterial blood pressure during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in systolic blood pressure during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in diastolic blood pressure during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in heart rate during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in cardiac output during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in stroke volume during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in total peripheral resistance during acute exercise
For the acute exercise intervention, the absolute change from pre-acute exercise to during steady-state exercise will be assessed.
Time frame: Pre-acute exercise and during 5 minutes of steady-state exercise
Change in renal blood flow velocity during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in mean arterial blood pressure during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in systolic blood pressure during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in diastolic blood pressure during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in heart rate during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in cardiac output during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in stroke volume during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in total peripheral resistance during cold pressor test
For the cold pressor test intervention, the absolute change from pre-cold pressor test to 30-second intervals during the cold pressor test will be assessed.
Time frame: Pre-cold pressor test to after 30, 60, 90, and 120 seconds of cold pressor test
Change in renal blood flow velocity during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in mean arterial blood pressure during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in systolic blood pressure during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in diastolic blood pressure during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in heart rate during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in cardiac output during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in stroke volume during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
Change in total peripheral resistance during mental stress test
For the mental stress test intervention, the absolute change from pre-mental stress test to 1-minute intervals during the mental stress test will be assessed.
Time frame: Pre-mental stress test to after 1, 2, 3, 4, and 5 minutes of mental stress test
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