Pre-diabetes (Pre-D) is a precursor to type 2 diabetes (T2D) and characterized by increased exercise fatigability of lower limb muscles, that can impede exercise performance. The cause for the increased fatigability in people with Pre-D is not known. Given the profound vascular disease present in people who have had uncontrolled diabetes for several years, we will determine whether dynamic, fatiguing contractions of the lower limb muscles in people with Pre-D are limited by vascular dysfunction at multiple levels along the vascular tree including the artery, arteriole, and/or capillary. This clinical trial involves a novel exercise training regime involving blood flow restriction to the exercising limb will be used as a probe to further understand the vascular mechanisms for increased fatigability in people with Pre-D and T2D. The long-term goal is to better understand what limits exercise and functional performance in people with diabetes to help develop targeted, more effective exercise programs.
The aim of the clinical trial is to determine the effectiveness of dynamic resistance exercise training coupled with blood flow restriction to improve fatigability and vascular function in people with Pre-D and T2D. People with Pre-D and T2D from Aim 1 will perform 8 weeks of dynamic unilateral resistance exercise training in which one leg is exercised with freely perfused conditions and the other leg with blood flow restriction. We will assess fatigability, skeletal muscle metabolism, capillary density, and vascular function in people with Pre-D and T2D before and after a novel training intervention that couples dynamic resistance training with blood flow restriction to the exercising limb. This novel intervention has been shown to improve vascular function in young and older adults but has not been investigated in people with Pre-D and T2D. Endothelial function in intact large conduit arteries and arterioles isolated from skeletal muscle biopsies will be measured before and after the training intervention to assess whether the novel training improves vascular function along multiple levels of the vascular tree in people with Pre-D and T2D. Skeletal muscle blood flow through the femoral artery will be quantified with Doppler ultrasonography and skeletal muscle oxygenation will be measured with near infrared spectroscopy (NIRS) during a dynamic fatiguing knee extension exercise. We will closely match participant groups for physical activity levels, age, sex, and body mass index (BMI), because these confounders are not typically controlled for in other human studies.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
80
Each participant will attend 3 sessions per week for 8 weeks. Participants will perform low-load knee extension resistance training (20% of 1-RM) without blood flow restriction on the designated leg for 4 sets of contractions with 15 contractions per set of contractions with a 30 second rest between each set of contractions.
Each participant will attend 3 sessions per week for 8 weeks. Participants will perform low-load knee extension resistance training (20% of 1-RM) with blood flow restriction on the designated leg for 4 sets of contractions with 15 contractions per set of contractions with a 30 second rest between each set of contractions.
University of Michigan
Ann Arbor, Michigan, United States
RECRUITINGFatigability - Reduction in Power
Reduction in limb power and maximal force in response to a dynamic fatiguing contraction.
Time frame: One session before and then after 8 weeks of training
Strength - 1 Repetition Maximum
Reduction in limb power and maximal force in response to a dynamic fatiguing contraction
Time frame: One session before and then after 8 weeks of training
Strength - Maximal Voluntary Contraction (MVC)
Changes in MVC after 8 weeks resistance training. MVC is the greatest force generated during a brief isometric contraction.
Time frame: One session before and then after 8 weeks of training
Leg Blood Flow
Femoral artery mean blood velocity and femoral artery diameter will be measured using Doppler ultrasonography before and immediately after the fatiguing task in each leg.
Time frame: One session before and then after 8 weeks of training
Skeletal Muscle Oxygenation
Near-Infrared Spectroscopy recordings will be used to quantify blood flow kinetics of the knee extensor muscle tissue (rectus femoris and vastus lateralis) during the dynamic, fatiguing exercise in each leg.
Time frame: One session before and then after 8 weeks of training
Vasodilation in Skeletal Muscle Arterioles
Vessel diameters of arterioles that are extracted and isolated from Skeletal muscle biopsies of the vastus lateralis will be measured in response to vasodilators and constrictors
Time frame: One session before and then after 8 weeks of training
Muscle Metabolism - Phosphorus Nuclear Magnetic Resonance Spectroscopy (31P-MRS))
31P-MRS is used to noninvasively measure muscle metabolism by calculating intracellular ATP, ADP, phosphocreatine (PCr), inorganic phosphate (Pi), and pH in the quadriceps of participants. This measurement is conducted while participants perform fatiguing knee extensor exercise in the magnetic bore.
Time frame: One session before and then after 8 weeks of training
Capillary density
Immunohistochemical analysis will be performed on muscle biopsy samples to determine the number and density of capillaries for each fiber type.
Time frame: One session before and after 8 weeks of training
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