Background: Low-frequency neuromuscular electrical stimulation (NMES) attenuates the loss of muscle mass of Intensive Care Unit (ICU) patients. However, it has been shown that medium-frequency NMES may be better than low-frequency for the maintenance of skeletal muscle mass in healthy subjects. Objective: to compare the effects of low-frequency and medium-frequency NMES, along with a standard physical therapy (SPT) programme, on the attenuation of skeletal muscle atrophy in critically ill patients. Methods: Fifty-four critically ill patients admitted into intensive care unit (ICU) and on mechanical ventilation (MV) participated in this randomized, single-blinded, experimental study. Participants were allocated to one of the following groups: Control Group (CG), received a standard lower limb physical therapy (SPT) programme, 2x/day; Low-frequency NMES Group (LFG), received lower limb SPT+NMES at 100 Hz, 2x/day; and Medium-frequency NMES Group (MFG), received lower limb SPT+NMES at 100 Hz and carrier frequency of 2500 Hz, 2x/day. The primary outcome was the thickness and quality of the quadriceps muscle, evaluated with ultrasonography while patients were in ICU. Secondary outcomes, assessed at various stages of recovery, were strength, functionality, independence for activities of daily living, quality of life, and total days hospitalized.
Background: Low-frequency neuromuscular electrical stimulation (NMES) attenuates the loss of muscle mass of Intensive Care Unit (ICU) patients. However, it has been shown that medium-frequency NMES may be better than low-frequency for the maintenance of skeletal muscle mass in healthy subjects. Research question: The research question was is medium-frequency neuromuscular electrical stimulation (NMES) more effective than low-frequency NMES for the attenuation of skeletal muscle atrophy in critically ill patients? Objective: To compare the effects of low-frequency and medium-frequency NMES, along with a standard physical therapy (SPT) programme, on the attenuation of skeletal muscle atrophy in critically ill patients. Methods: Fifty-four critically ill patients admitted into intensive care unit (ICU) and on mechanical ventilation (MV) participated in this randomized, single-blinded, experimental study. Participants were allocated to one of the following groups: Control Group (CG), received a standard lower limb physical therapy (SPT) programme, 2x/day; Low-frequency NMES Group (LFG), received lower limb SPT+NMES at 100 Hz, 2x/day; and Medium-frequency NMES Group (MFG), received lower limb SPT+NMES at 100 Hz and carrier frequency of 2500 Hz, 2x/day. The primary outcome was the thickness and quality of the quadriceps muscle, evaluated with ultrasonography while patients were in ICU. Secondary outcomes, assessed at various stages of recovery, were muscle strength (MRC-SS), handgrip strength (dynamometry), functional status (FSS-ICU), degree of independence for activities of daily living (Barthel Index), functional mobility and dynamic balance (Timed Up and Go Test), quality of life (SF-36), and total days hospitalized.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
SINGLE
Enrollment
54
All participants have received standard physical therapy (SPT) sessions based on a passive range of motion mobilization protocol for the lower limbs. It consisted of a bilateral series of 10 repetitions of hip flexion, knee flexion and extension, and ankle flexion and extension. The procedure was performed twice a day: a morning (between 8am - 12pm) and an afternoon session (between 2pm - 6pm).
Electrical stimulation was performed twice a day after SPT. Two electrodes were attached to each thigh at the motor points of the quadriceps muscle. The point halfway between the anterior superior iliac spine and the base of the patella was used as reference and electrodes were placed 15 cm apart each other, 5 cm proximal and 10 cm distal from the reference point. After the first measurement, semi-permanent markers were used to indicate the position of electrodes. Electrical stimulation was performed using a 4-channels device (Sonopuls 492, series 4, Enraf-Nonius®, Rotterdam, Netherlands). The low-frequency protocol consisted of 100 Hz and 400 ms width pulses, delivered in trains of 5 s ON (ramp-up time: 1 s, plateau: 3 s, ramp-down time: 1 s) and 10 s OFF. Sessions had 20 min of duration (total of 40 min/day) and the current amplitude (mA) was adjusted to the identification of visible and palpable contractions and was rectified every 3 min to sustain the initial level of contraction.
Electrical stimulation was performed twice a day after SPT. Two electrodes were attached to each thigh at the motor points of the quadriceps muscle. The point halfway between the anterior superior iliac spine and the base of the patella was used as reference and electrodes were placed 15 cm apart each other, 5 cm proximal and 10 cm distal from the reference point. After the first measurement, semi-permanent markers were used to indicate the position of electrodes. Electrical stimulation was performed using a 4-channels device (Sonopuls 492, series 4, Enraf-Nonius®, Rotterdam, Netherlands).The medium-frequency protocol had similar parameters, but a carrier frequency of 2500 Hz and burst frequency of 100 Hz. Sessions had 20 min of duration (total of 40 min/day) and the current amplitude (mA) was adjusted to the identification of visible and palpable contractions and was rectified every 3 min to sustain the initial level of contraction.
Department of Internal Medicine, Faculty of Medicine, Universidad de La Frontera
Temuco, Chile
Change in thickness of the quadriceps muscle, evaluated with ultrasonography while patients were in intensive critical unit (ICU).
Thickness of the quadriceps muscle via ultrasonography (mm).
Time frame: Day 1, Day 5, Day 9
Change in quality of the quadriceps muscle, evaluated with ultrasonography while patients were in intensive critical unit (ICU).
Quality of the quadriceps muscle via ultrasonography by Heckmatt's rating scale. Muscle quality was estimated by Heckmatt's rating scale, which scores the ultrasound images between 1-4: 1) normal echogenicity; 2) slight increase in muscle echogenicity and normal bone reflection; 3) moderate increase in muscle echogenicity and reduced bone reflection; 4) large increase in muscle echogenicity and no bone reflection.
Time frame: Day 1, Day 5, Day 9
Change in Clinical assessment of muscle strength while patients were in intensive care unit (ICU).
Clinical assessment of muscle strength via Medical Research Council-Sum Score (MRC-SS) (points), which ranges from 0 (complete paralysis) to 60 (normal strength).
Time frame: Day 9, Day 11, Day 16, and Day 27
Change in Handgrip strength while patients were in hospital stay.
Handgrip strength via digital dynamometer (kg).
Time frame: Day 9, Day 11, Day 16, and Day 27
Change in Functional status while patients were in Intensive Care unit (ICU).
Functional status via Functional Status Score for the Intensive Care Unit (FSS-ICU) (points). FSS-\]ICU FSS-ICU score has a range of 0-35 with higher score indicating better functional status.
Time frame: Day 9, Day 11, Day 16, and Day 27
Change in dynamic balance while patients were in hospital stay.
Dynamic balance via Timed Up and Go Test (seconds).
Time frame: Day 16, and Day 27
Change in independence for activities of daily living while patients were in hospital stay.
Independence for activities of daily living via Barthel index (points). A patient scoring 0 points would be dependent in all assessed activities of daily living, whereas a score of 100 would reflect independence in these activities.
Time frame: Day 16, and Day 27
Change in quality of life prior to hospital discharge.
Quality of life via Short Form 36 (SF-36) (points). The score go from 0 to 100. Higher scores mean a better outcome.
Time frame: Day 27
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