Clinical Trial Details
— Status: Completed
Administrative data
NCT number |
NCT01345461 |
Other study ID # |
25428 |
Secondary ID |
|
Status |
Completed |
Phase |
N/A
|
First received |
April 15, 2011 |
Last updated |
September 27, 2017 |
Start date |
January 2010 |
Est. completion date |
June 2011 |
Study information
Verified date |
September 2017 |
Source |
Rigshospitalet, Denmark |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Observational
|
Clinical Trial Summary
As the critical care practice has improved over the last decades more patients are recovering
from intensive care therapy. However, muscle atrophy and neuromuscular dysfunction are
commonly observed sequelae after critical illness and are thought to play important roles in
the development of intensive care unit acquired weakness (ICUAW). As a consequence, these
entities may contribute to the impaired physical function and prolonged convalescence
reported by ICU patients up to twelve months after discharge. Thus, strategies to counteract
muscle atrophy and neuromuscular dysfunction acquired during the ICU stay may therefore
potentially improve physical outcome and reduce the overall burden of critical illness.
Limited information is available on muscle function in ICU patients and to our knowledge no
muscle stimulation methods are currently available for evaluating muscle fatigue in large,
proximal muscles groups, such as m. quadriceps, in non-cooperating ICU patients.
Description:
Positioning of the subject: A special device, consisting of a rigid padded wooden board
resting on metal bar, which was attached to the metal framing of the hospital bed, held the
knee joint at a 90-degree angle and secured firm support of the entire thigh (Fig. 1). The
positioning was chosen to reduce unnecessary movement and minimize risk for mechanical
ventilated ICU patients. Isometric knee extension forces were therefore measured while
subjects were placed in a supine position in a hospital bed with a 30-degree incline of the
head and torso.
Electrical muscle stimulation: Two carbon electrode pads were placed distally over the motor
point of the medial (vastus medialis) and lateral (vastus lateralis) heads of the quadriceps
muscle. The motor point was defined as the location that corresponded to the lowest possible
threshold current and the motor threshold current was defined as the lowest train stimulation
current that resulted in visible muscle contraction. Another pair of electrodes (5x9 cm) was
placed 5 cm distal to the inguinal fold (10). To optimize electrical conduction, the skin was
shaved and rinsed before applying the electrodes. This approach was similar to previous
studies (11).
Initially, two constant current high voltage stimulators delivered ten single stimuli
twitches with biphasic square pulses at widths of 300 μs. A train generator was then switched
on, triggering the delivery a 35 Hz current in bouts of 3 seconds periods separated by
1-second pause for a total of 40 tetanic contractions. In immediate succession to the tetanic
contractions a second series of ten single twitch stimuli ended the protocol. Figure 2 show
an example of an actual recording of the force response curve.
On the first experimental day testing current was adjusted to 75% above the motor threshold
current. On the second testing day, training intensity was determined as the stimulation
intensity corresponding to the same force output level (mV) as generated by the first tetanic
contraction on the first testing day, while maintaining the same ratio between the medial and
the lateral intensity levels.
The stimulation parameters and the two-channel stimulation method were chosen in order to
increase the amount of stimulated muscle mass, ensure a safe, tetanic contraction in the
non-cooperating subjects; to reduce risk of excessive muscle damage and to avoid recruitment
of sensory fibers and thus minimize discomfort.
Force measurements: A height adjustable strain gauge, placed beneath the bed, were secured to
the metal framing of the bed and connected horizontally (180 degree) to the subjects with a
non-extensible strap placed around the angle of the subject. To minimize leg movement a
second non-extensible strap were attached between the ankle and a fixed metal bar, pulling
directly opposite the strap holding the strain gauge. A bridge circuit was used to detect
changes in relative resistance in the strain gauge and transformed voltage changes,
proportional to the torque generated by the activated muscle, were then A/D converted,
sampled at 1 kHz and subsequently stored on a personal computer for further offline analysis.
Off line data analysis All motor current threshold values were the average of two
measurements per side.
Tetanic contractions: To ensure attainment of plateau level of contractions torque values
were calculated as the mean of the last second of the 3-s contraction. Peak tetanic torque
values were the highest obtained value. The tetanic stimulation period was subdivided into
five intervals where interval 1 corresponds to the first 60 seconds (1-15 contractions),
interval 2 from 61-120 seconds (16-30 contractions), interval 3 from 121-160 seconds (31-40
contractions), interval 4 the first 120 seconds (1-30 contractions) and interval 5 to the
total period of 160 seconds (1-40 contractions). For each interval the resistance to muscle
fatigue was expressed as a Fatigue Index (FI) and calculated as the ratio between the sum of
peak torque values from the final three contractions relative to the sum of peak torque
values from the first three contractions. Furthermore were peak torque values for each
contraction plotted and the slope of the regression line for each interval calculated.
Twitch contractions: All data were 15Hz low pass filtered and peak torque and rise-time were
calculated before and after the tetanic stimulation period. For each 10-twitch series peak
torque and rise-time (the slope between 30% and 70% of the twitch peak force, Nm/s) was
calculated for the individual twitches. Both peak torque and rise-time were then expressed as
the average values of all twitches before and after the tetanic contraction.
Data integrity:
Care was taken to ensure identical study conditions and uniformity in regard to time of day,
location, equipment and procedure. Furthermore, all tests were conducted in a
temperature-controlled environment with a single observer assessment and measurements regime
maintained throughout the study. The same investigator (JBP), who was blinded to the
intensity level, determined all threshold values and MR conducted all on-line muscle force
measurements. To ensure optimal comparison between the two experimental secessions subjects
were placed in a standardized position securing uniformity of posture, joint positions and
orientation of the thigh. To reduce day-to-day variations in electrode placement on the
thigh, these were marked, along with at least three permanent landmarks, on a transparent
paper, thus serving as a "map" for a precise identification. On day seven the same
investigator (JBP) then carefully replaced the electrodes identical to day 1. On both testing
days, gauges were calibrated and each subject received a short standardized low intensity
familiarisation session prior to the testing procedure to ensure potentiation of muscle
tissue during which electrical muscle stimulation and the present protocol were carefully
explained. Left/right testing order was determined after randomisation with the same order of
testing maintained on the second experimental day. Subjects were instructed to be as relaxed
as possible and to suppress any voluntary contraction during the test. Finally, to ensure the
quality of the recorded data, knee extension forces were immediately displayed on-line on a
computer screen for visual inspection.