This study focuses on physiological explanations of difficulties with physical activity and exercise in individuals with Down syndrome, by non-invasively examining cardiac output and the regulation of blood flow to working muscles during exercise.
Work capacity is an important predictor of declining health or physical function, and of mortality, and is commonly measured as peak oxygen consumption. Peak oxygen consumption is very low in individuals with Down syndrome, the most prevalent genetic cause of intellectual disability. Previous research suggests individuals with Down syndrome may experience a double disadvantage when they are exercising: they may not be able to increase cardiac output sufficiently and they may not be able to allocate adequate blood flow to the working muscles. The aim of this research study is therefore to determine the impact of limitations in central and peripheral regulation of blood flow on work capacity in individuals with DS. The results of this project will aid our understanding of the underlying mechanisms and determine the potential to improve health across the lifespan of individuals with Down syndrome by tailoring exercise interventions.
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
SCREENING
Masking
NONE
Enrollment
21
For participants with Down syndrome, the first visit includes baseline measures and familiarization with the graded maximal exercise test protocol. If necessary, additional familiarization sessions will be scheduled for people with Down syndrome. The second visit, we perform the graded maximal exercise test and familiarize the participant with the procedures for the third visit: the hand grip exercise protocol and the lower body negative pressure (LBNP) box. The third visit we assess the peripheral blood flow during the hand grip exercise protocol without and with the LBNP. For control subjects, the first and second visit are combined. Their second visit is the same as the third visit for individuals with Down syndrome.
Disability, Health, and Social Policy Building, Integrative Physiology Laboratory, Suite 158 at 1640 W. Roosevelt Rd
Chicago, Illinois, United States
Brachial blood flow
Forearm blood flow and vascular conductance will be measured in both the exercising and non-exercising arm using high definition ultrasound (Alpha 7, Aloka-Hitachi). The brachial artery will be imaged in dual mode allowing for simultaneous determination of artery diameter (B-mode) and flow velocity (Doppler mode). Blood flow will be determined from the following formula: Forearm Blood flow = (Mean blood velocity) x (Brachial Cross Sectional Area) x (60) and expressed as ml/min. Forearm vascular conductance will be determined by dividing forearm blood flow by mean arterial pressure. Forearm blood flow and vascular conductance will be normalized to forearm lean mass to account for differences in lean mass between individuals.
Time frame: In minute 4 of the 5-minute bout of grip strength exercise
Muscle oxygenation
Muscle oxygenation will be measured with near-infrared spectography (NIRS), which is a simple, noninvasive method for measuring the presence of oxygen in muscle. It can monitor changes in muscle oxygenation and blood flow during submaximal and maximal exercise. During exercise, the extent to which skeletal muscles deoxygenate varies according to the type of muscle, type of exercise and blood flow response.
Time frame: In minute 4 of the 5-minute bout of grip strength exercise
Cardiac outut
Cardiac output will be measured during a graded maximal test protocol using ultrasonography, by measuring the aortic diameter at the level of the valve form the peristernal long axis. Ascending aortic blood flow will be measured using continuous Doppler echocardiography using a pedoff probe in the suprasternal notch.
Time frame: Every second minute until the 12th minute of the maximal test.
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