Healthy Clinical Trial
Official title:
Non-invasive Measurement of Microvascular Blood Flow During Mild External Compression of the Leg
SPECIFIC AIMS
The limbs of diabetic patients are associated with decreases in capillary density, arterial
inflow, and local blood flow of the leg. Decreased perfusion adversely affects wound healing
and viability of tissue, especially in patients with peripheral vascular disease and
diabetes. The investigators hypothesize that mild external compression can restore the
decreases in skin and muscle blood flow and that there would be greater increases in
microvascular blood flow induced by leg compression compared to healthy subjects. Blood flow
will be measured using Photoplethysmography (PPG) before, during, and after external
compression, and muscle oxygenation will be measured with Near Infrared Spectroscopy (NIRS).
The specific aims are:
- To measure Muscle Blood Flow (MBF), Skin Blood Flow (SBF), and Bone Blood Flow (BBF)
microcirculatory alterations in the leg and foot caused by mild external compression in
healthy subjects and patients with diabetes.
- To measure muscle oxygenation changes in the leg and foot caused by mild external
compression in healthy subjects and patients with diabetes.
- To optimize pressures of Continuous Compression to induce maximum microcirculatory
blood flow in healthy subjects and patients with diabetes.
- To optimize compression pressures, duration, and frequency of Intermittent Pneumatic
Compression (IPC) to induce maximum microcirculatory blood flow in healthy subjects and
patients with diabetes.
- To measure microcirculatory response to compression in patients with diabetes
- Continue to validate of photoplethysmography as a tool for measuring microcirculation.
BACKGROUND AND SIGNIFICANCE
Therapies utilizing external compression of the leg prevent deep venous thrombosis, decrease
lower extremity edema, manage chronic venous insufficiency, and increase healing in the
treatment of venous stasis ulcers. In diabetic patients' feet, microcirculation is
compromised leading to increased chances of ulcer formation. Therefore, therapies utilizing
compression of the lower leg could be beneficial to this population as compression therapies
have shown to increase limb perfusion. In recent decades, investigators have found that
intermittent compression of the calf or foot can produce acute increases in arterial inflow
to a limb. Moreover, intermittent pneumatic compression at high pressures (120 mmHg)
increases skin perfusion and popliteal artery inflow. Compression stockings produce much
lower pressures (around 20-40 mmHg) but still aid in ulcer healing. The commercial systems
have used rapid compression lasting for 3 s or less, with foot and calf pressures (80-100
mmHg). Longer compression durations (10 s at 60 mmHg) with moderate inflation rates in
supine patients are effective in increasing flow velocity in the femoral artery, which means
that systems do not necessarily need high levels of compression and rapid inflation periods
that can be uncomfortable. An optimal therapy for individual patients with peripheral
vascular disease should increase microvascular flow in the limb for the longest period
possible.
Relatively little is known about local circulation in the context of treatment of venous
disease with compression therapies. It is known that venous disease decreases muscle and
skin oxygenation, and that there are acute and chronic physiologic adaptations to
compression therapies such as increases in large and small vessel blood flow and capillary
growth. Compression pressures ranging from 20-120 mmHg are used, but there is little
physiologic evidence to support an optimal pressure for therapy. Little previous research
has looked at the duration of hyperemia during external compression, but for the purpose of
therapy it is important, since a compression cycle must set to maximize periods of
hyperemia. Another unknown is whether intermittent compression increases blood flow to a
greater extent compared to continuous compression. The major variables in compression
therapies are compression pressure, duration of compression, and the frequency of
compression. The investigators are not aware of any studies to date that have examined these
variables in the context of skin and muscle microvascular blood flow in the leg.
Photoplethysmography (PPG) is a non-invasive optical technique that measures local
microvascular blood flow. PPG directs light from a light emitting diode (LED) toward the
skin; light is scattered and absorbed by the skin and deeper tissues. Green light LEDs are
placed close to the photodetector to measure skin blood flow. Infrared LEDs are placed
farther from the photodetector and penetrate up to several centimeters into underlying
muscle. Blood flow changes in the tissue cause changes in the intensity of scattered light
recorded by the photodetector. This technique has been validated in multiple studies against
invasive methods and is considered to be the best non-invasive measurement of local muscle
blood flow. For skeletal muscle, PPG provides equivalent results when compared with the
invasive laser Doppler technique. However, frequent motion artifacts and local tissue trauma
limit laser Doppler's usefulness. In patients with central venous hypertension due to heart
failure, it is hypothesized that increases in compression-induced leg muscle microvascular
blood flow will occur in proportion to increases in central venous pressure. It is also
hypothesized that in patients with diabetes, increases in compression-induced foot
microvascular blood flow will occur in proportion to increases in central venous pressure.
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Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Basic Science
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