Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05528549 |
| Other study ID # |
2022-0310 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
Phase 3
|
| First received |
|
| Last updated |
|
| Start date |
September 1, 2022 |
| Est. completion date |
April 26, 2023 |
Study information
| Verified date |
April 2024 |
| Source |
University of Illinois at Chicago |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Down syndrome (DS) is a chromosomal condition that occurs in approximately 1 in 800 births
worldwide, and causes impairments in physical function, including a reduced work capacity (as
measured by VO2peak or aerobic capacity). Work capacity is important for activities of daily
living, in order to live longer, healthier lives. Reduced work capacity stems in large part
from autonomic dysfunction, which has been described in individuals with DS. Individuals with
DS experience reduced sympathetic and parasympathetic control, which results in alterations
in resting heart rate, blood pressure, and attenuated responses to sympathoexcitatory
stimuli. Autonomic dysfunction may impair the ability to regulate blood flow and blood
pressure to working muscles during exercise, which may cause a mismatch between oxygen supply
and demand, further compromising the already reduced work capacity observed in individuals
with DS. Utilization of a large muscle mass exercise, such as lower-limb dynamic exercise
(similar to walking), requires a large shift in blood flow to match metabolic demand and
allows the opportunity to evaluate blood flow regulation. Conversely, examination of the
large changes in pressure in response to isometric exercise (i.e., a sustained contraction),
allows for examination of the exercise pressor reflex as evoked by the isometric contraction.
Thus, by comprehensively evaluating blood flow and blood pressure regulation, our work will
further elucidate the mechanisms that underlay the reduced work capacity in individuals with
DS. Improvement of overall work capacity for a population with reduced work capacity will
guide future studies and exercise interventions aimed at helping to improve independence and
quality of life, ultimately allowing individuals with DS to live longer, healthier lives.
Aim 1 (Dynamic Exercise): To examine the effects of an acute bout of dynamic leg kicking at
both relative and absolute intensity workloads on femoral blood flow to both exercising and
non-exercising muscle, in individuals with and without DS.
Aim 2 (Isometric Exercise): To examine the exercise pressor response to lower limb isometric
exercise in individuals with and without DS.
Description:
Specific Aims
Down Syndrome (DS) is the most prevalent genetic form of intellectual disability, and
individuals with DS have low work capacity. Reduced work capacity limits gross motor
function, and thus, reduces independence, full participation, and ultimately quality of life
(QOL). Low work capacity is associated with central autonomic dysfunction in persons with DS,
which limits maximal heart rates ~30 beats below expected values. However, during exercise,
the autonomic nervous system also balances peripheral blood flow delivery and blood pressure
regulation, through the redistribution of blood to active skeletal muscle. Blood flow
redistribution occurs primarily through sympathetically-mediated changes in vasomotor tone by
stimulation of mechanically and metabolically sensitive afferent fibers in the skeletal
muscle, which results in changes in pressure to maintain adequate flow. It is unknown whether
the observed central autonomic dysfunction in individuals with DS also alters peripheral
blood flow regulation or the blood pressure response to lower limb exercise, which is
critical to improving work capacity and ultimately participation and QOL.
Blood flow redistribution occurs in an intensity-dependent manner regulated through changes
in pressure, away from inactive tissue towards exercising or active muscle through
vasoconstrictive mechanisms. Data from our lab using a mild sympathetic stimulus, namely
lower body negative pressure, suggests individuals with DS have reduced vasoconstrictive
control. Reduced ability to vasoconstrict inactive tissue during exercise may inhibit
appropriate distribution of blood flow to active muscle, which may be particularly limiting
during large muscle exercise, thereby limiting work capacity. In addition to reduced
vasoconstrictive control, blood flow during exercise is driven by sympathetically-mediated
increases in blood pressure from muscular contraction activating the mechano- and
metaboreflexes, termed the exercise pressor reflex. Individuals with DS have a blunted blood
pressure response to sympathoexcitatory challenges, such as isometric handgrip exercise,
suggesting impairments in blood pressure regulation. Taken together, our previous work (i.e.,
preliminary data) suggests that the redistribution of blood flow and blood pressure
regulation may be impaired during stimuli involving small muscle mass for individuals with
DS. However, blood flow and blood pressure regulation have not been examined using large
muscle exercise (e.g., lower limb exercise) in DS, which may be a more impactful and limiting
factor for individuals with DS in regards to work capacity.
Active, lower limb exercise requires greater peripheral blood flow regulation to ensure a
match between oxygen demand and supply, which is critical to improving blood pressure
regulation and thus, work capacity. The aim of this study is to comprehensively evaluate
blood flow redistribution by examining blood flow to active and non-active legs during
dynamic (rhythmic muscular activity) lower limb exercise with increasing exercise intensity.
In contrast, isometric (contraction of muscles without movement in surrounding joints) lower
limb exercise will allow for investigation of blood pressure regulation in individuals with
DS through activation of the exercise pressor reflex. More specifically, the metaboreflex can
be assessed with post-exercise ischemia that traps metabolites in a regional area, wherein
blood pressure and sympathetic activity remain elevated, independent of cardiac output.
Interestingly, neither blood flow redistribution nor the exercise pressor response to large
muscle exercise have been previously explored in individuals with DS. Investigation of these
mechanisms will help elucidate the mechanisms of low work capacity, ultimately leading to
improved health outcomes, participation, and QOL for individuals with DS.
The overall aim of this study is to comprehensively evaluate blood flow regulation, including
the pressor reflex, in two research aims: Aim 1 (Dynamic Exercise): To examine the effects of
lower limb dynamic exercise on femoral blood flow in both exercising and non-exercising legs
in individuals with and without DS. The investigators hypothesize individuals with DS will
have: a) attenuated femoral blood flow to the active leg at all intensity workloads of
dynamic exercise and b) a lack of blood flow control as demonstrated by a lack of
vasoconstriction in the non-exercising leg compared to individuals without DS. Aim 2
(Isometric Exercise): To examine the effects of lower limb isometric exercise on the exercise
pressor response in individuals with and without DS. The investigators hypothesize the
individuals with DS will exhibit an attenuated blood pressure response, demonstrating
dysfunction of the exercise pressor reflex following isometric single-leg extension.
