Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05203653 |
| Other study ID # |
Pro00115197 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
March 1, 2022 |
| Est. completion date |
March 19, 2023 |
Study information
| Verified date |
March 2023 |
| Source |
University of Alberta |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Certain types and timings of exercise are known to cause hyperglycemia (high blood glucose)
in people with type 1 diabetes. Hyperglycemia increases the risk of most long-term
complications for individuals with this complication. However, using insulin corrections to
treat post-exercise hyperglycemia can increase the risk of late-onset hypoglycemia (low-blood
glucose).
Anaerobic activities performed in a fasted state are known to cause increases in blood
glucose and post-exercise hyperglycemia in most individuals with type 1 diabetes. This study
proposes to examine the effect of a ten-minute aerobic cool down after resistance exercise on
the blood glucose response to fasted exercise of individuals with type 1 diabetes. It is
hypothesized that adding a short aerobic cool down at the end of a fasted resistance exercise
session will attenuate post-exercise increases in blood glucose observed in previous studies,
leading to less post-exercise hyperglycemia.
Description:
Individuals with type 1 diabetes (T1D), are at elevated risk of low muscular strength, as
well as accelerated decline in muscle strength and functional status with aging. Resistance
exercise (RE) is a proven intervention that has been demonstrated to improve physical
function, muscle mass, body composition, mental health, bone mineral density, insulin
sensitivity, blood pressure, lipid profiles, and cardiovascular health for all adults.
Clinical guidelines recommend that individuals with T1D perform RE twice weekly to optimally
benefit from RE yet most individuals with T1D are unable to meet these recommendations. Two
barriers to exercise responsible for this discrepancy are a fear of hypoglycemia from
exercise, and a loss of control over diabetes. To limit barriers to exercise, much research
has been done to identify exercise modalities that have minimal risk for hypoglycemia,
including recent investigations demonstrating a blood glucose increase leading to
hyperglycemia in response to RE while participants are fasted. Hyperglycemia frequency is
directly related to the incidence of diabetes-related complications, so exercise
recommendations should minimize risk of hyperglycemic and hypoglycemic responses. Clinical
guidelines for post-exercise hyperglycemia recommend a corrective insulin dose or a brief
aerobic cool down, however the efficacy of an aerobic cool down has yet to be empirically
tested. Additionally, overcorrection of hyperglycaemia with insulin after exercise can result
in an increased risk of severe late onset hypoglycaemia, which could even be fatal.
The study will have a randomized, repeated measures design with two testing sessions (one
with a cool down and one without a cool down) in addition to a baseline fitness assessment.
Interested participants will be invited to the Physical Activity and Diabetes Laboratory on
the main campus of the University of Alberta. Participants will be asked questions related to
diabetes care, physical activity levels, and medication. Blood pressure and heart rate will
also be measured. Where participants are eligible, anthropometric characteristics will be
measured using standard protocols. Those who meet all eligibility criteria and complete
informed consent forms will be asked to complete the initial exercise tests. Participants
will perform a submaximal aerobic capacity test to extrapolate the participant's aerobic
capacity. Participants will also undergo a strength test for each of the seven exercises
involved in the study, in order to estimate the maximum weight they can move for 3 sets of 8
repetitions (8RM). During this session the investigators will introduce participants to the
activity monitor (accelerometer) that will be worn on the day before, the day of, and the day
after each testing session. The accelerometer will provide information on background physical
activity and sleep patterns that might act as confounders where the blood glucose responses
to exercise are concerned.
Testing sessions: Participants will be asked to arrive at the lab between 7:00 and 8:00 am
for both sessions, which will be randomly assigned by tossing a fair coin. During the
sessions, participants will be asked to perform a total of seven resistance exercises (leg
press, chest press, leg curls, lat pulldowns, seated row, shoulder press, and abdominal
crunches). The protocol will be 3 sets of 8 repetitions at the participant's 8 RM.
Participants will be asked to match their daily food and insulin intake as closely as
possible from one testing session to the next for the day before, day of and day after the
testing session. During this time participants will also wear an accelerometer on their waist
during the day, and on their non-dominant wrist at night. Participants will be provided with
log sheets to assist in both of these tasks and will also be asked to avoid strenuous
exercise and alcohol intake.
A CGM sensor will be subcutaneously inserted by one of the investigators (trained by a group
from the CGM manufacturer) into the anterior abdominal area of the participant approximately
2 days prior to the first testing session. The Dexcom G6 CGM will store glucose data every 5
minutes for up to 10 days. The participant will be instructed on how to remove their sensor
at least 24 hours after the exercise session, and will be asked to upload their data to
Dexcom Clarity to share with the study team. If the participant habitually uses their Dexcom
G6 in their diabetes care, they will be provided with the option to start their own CGM for
the study.
