Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT05772819 |
| Other study ID # |
NL83611.042.23 |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
April 1, 2023 |
| Est. completion date |
June 1, 2024 |
Study information
| Verified date |
March 2023 |
| Source |
University Medical Center Groningen |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Surgery remains an important treatment modality in the treatment of hepatopancreatobiliary
(HPB) malignancies, but the physiological stress caused by surgery is at the same time a
challenge for the homeostasis of patients. A patient's preoperative aerobic capacity has been
found to have a consistent relation with postoperative outcomes in major abdominal surgery,
with low aerobic capacity being associated with a higher risk of postoperative morbidity and
mortality. Preoperative exercise prehabilitation programs can effectively increase the
ability of patients to cope with surgical-induced allostatic load, by improving aerobic
capacity, and functioning of the respiratory, cardiovascular, and/or musculoskeletal systems.
However, besides the effect of exercise prehabilitation on physical fitness in terms of
improvement of aerobic capacity as measured by the cardiopulmonary exercise test (CPET), the
exact role of adaptations in cardiac and/or skeletal muscle function contributing to the
improvement in aerobic capacity is still unknown. Insight in the physiological adaptations
that lead to improvement in aerobic capacity after prehabilitation in patients with low
aerobic capacity will enable caregivers to individually optimize the exercise program (e.g.
by changing exercise frequency, intensity, duration and type) and better explain the
rationale and effectiveness behind the short-term physical exercise training program to
patients. Therefore, the main objective of this study is to assess the central (cardiac
function) and peripheral (skeletal muscle function) physiological adaptations in response to
short-term exercise prehabilitation. Secondary objective is to assess the relationship
between immune function and exercise. In this study, unfit patients are asked to undergo
additional in-magnet exercise testing to investigate the central and peripheral physiological
adaptations in response to exercise prehabilitation.
Description:
Rationale: Surgery remains an important treatment modality in the treatment of
hepatopancreatobiliary (HPB) malignancies, but the physiological stress caused by surgery is
at the same time a challenge for the homeostasis of patients. A patient's preoperative
aerobic capacity has been found to have a consistent relation with postoperative outcomes in
major abdominal surgery, with low aerobic capacity being associated with a higher risk of
postoperative morbidity and mortality. Preoperative exercise prehabilitation programs can
effectively increase the ability of patients to cope with surgical-induced allostatic load,
by improving aerobic capacity, and functioning of the respiratory, cardiovascular, and/or
musculoskeletal systems. However, besides the effect of exercise prehabilitation on physical
fitness in terms of improvement of aerobic capacity as measured by the cardiopulmonary
exercise test (CPET), the exact role of adaptations in cardiac and/or skeletal muscle
function contributing to the improvement in aerobic capacity is still unknown. Insight in the
physiological adaptations that lead to improvement in aerobic capacity after prehabilitation
in patients with low aerobic capacity will enable caregivers to individually optimize the
exercise program (e.g. by changing exercise frequency, intensity, duration and type) and
better explain the rationale and effectiveness behind the short-term physical exercise
training program to patients.
Objective: The main objective is to assess the central (cardiac function) and peripheral
(skeletal muscle function) physiological adaptations in response to short-term exercise
prehabilitation. Secondary objective is to assess the relationship between immune function
and exercise.
Study design: This study is a single-center prospective clinical trial with a one-group
pretest-posttest design. It will take place at the University Medical Center Groningen
(UMCG), the Netherlands. As part of standard care, all patients scheduled to undergo hepatic
or pancreatic surgery for (suspected) HPB malignancies at the UMCG are screened for low
aerobic capacity, and subjected to exercise prehabilitation in case of low aerobic capacity.
In this study, unfit patients are asked to undergo additional in-magnet exercise testing to
investigate the central and peripheral physiological adaptations in response to exercise
prehabilitation.
Study population: Unfit patients diagnosed with a (suspected) HPB malignancy who are
scheduled to undergo elective hepatic or pancreatic surgical resection and participate in the
exercise prehabilitation program. Intervention: In-magnet exercise test consisting of in vivo
exercise cardiac magnetic resonance (exCMR) imaging and 31P-magnetic resonance spectroscopy
(31P-MRS) during exercise testing in a MR-compatible ergometer, before and after the 4-week
prehabilitation program. In addition to exCMR imaging and 31P-MRS during rest, blood will be
withdrawn at three different time points (before first CPET, after first CPET and before
second CPET).
Main study parameters/endpoints: The difference in left and right ventricular function will
be measured by exCMR in rest, during progressive exercise, and recovery to assess the effect
of the preoperative physical exercise training program on cardiac function. The difference in
quadriceps phosphocreatine concentration (PCr), quadriceps inorganic phosphorus concentration
(Pi), and quadriceps pH at rest, during progressive exercise, and recovery rate will be
measured by 31P-MRS to assess the effect of the prehabilitation program on skeletal muscle
function. Differences in inflammatory and immunological cytokines and chemokines before the
first CPET, directly after the first CPET and before second CPET.
Nature and extent of the burden and risks associated with participation, benefit and group
relatedness: The intervention consists of four extra hospital visits. During these visits the
in-magnet exercise tests and blood sample collection (exCMR and 31P-MRS) will be performed.
The in-magnet exercise test can lead to physical discomfort, due to an uncomfortable feeling
while cycling on an ergometer whilst laying supine in the MRI. However, before the in-magnet
exercise test, a CPET in a controlled environment (continuous 12-lead electrocardiography
registration and under supervision of a sports physician) is performed and therefore the
in-magnet exercise test can be safely performed when the CPET does not show
contra-indications for exercise. The imaging consisting of exCMR and 31P-MRS has previously
been shown to be safe and is already widely used in different studies at the UMCG. Patients
are not exposed to any radiation and/or contrast agents. The blood samples that will be taken
are not expected to cause an extra risk/burden to the patients. Except for little
pain/discomfort, or the possibility of local hemorrhage which can easily solved by
compression of the vein
