Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05159986 |
| Other study ID # |
CT01306435 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
January 1, 2021 |
| Est. completion date |
August 1, 2021 |
Study information
| Verified date |
November 2021 |
| Source |
University of Sao Paulo General Hospital |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Osteoarthritis represents failed repair of joint damage resulting from stresses initiated by
any joint or periarticular tissue abnormality. The rate of progression varies among persons
and within a knee over time.
The symptoms and signs of knee osteoarthritis include pain, stiffness, reduced joint motion,
and muscle weakness. Long-term consequences can include reduced physical activity,
deconditioning, impaired sleep, fatigue, depression, and disability.This reduction in
activity to avoid pain (kinesiophobia) to evade the onset of pain, especially in the acute
phase, limiting their compliance with effective rehabilitation strategies such as regular
exercises.
Physical medicine has a wide range of analgesic anti-inflammatory and muscle stimulating
treatment methods. Both diadynamic and TENS currents have become the most frequently
implemented electrotherapeutic methods. The impact of diadynamic currents consists of
analgesic effects and specific dynamics during the formation of physiological processes in
tissues.
They occur during the administration of the current and lasts up to a few hours after the
treatment has been terminated. One of the theories explaining the analgesic effect of
diadynamic currents is the gate control theory of pain by Wall and Melzack. Recently, another
theory has become very popular. It explains the analgesic effect provoked by bodies
characterized as polypeptides called endorphins. Electric stimulation using diadynamic
currents generates an increase in the amount of endorphins in a system.
Although the analgesic impact of TENS therapy is well known, Diadynamic currents therapies
have not been studied in knee osteoarthritis pain conditions. Therefore, the aim of the
present study was to investigate the medium-term effects of Diadynamic currents combined with
exercise on pain and disability in patients with osteoarthritis of the knee.
Description:
The study included patients who attended the Special Rehabilitation Services in TaboĆ£o da
Serra-SP, with knee osteoarthritis diagnosed by an independent rehabilitation specialist, and
fulfilled the following inclusion criteria: (1) aged from 50 and 75; (2) symptomatic knee
osteoarthritis for at least three months; (3) visual analogue scale12 score above 3 and (4)
radiographic knee osteoarthritis (uni or bilateral) compatible with Kellgren-Lawrence grade
two or higher.
The exclusion criteria were as follows: contraindication to laser application (e.g. cancer
and insulin-dependent diabetes); inability to perform the assessment or treatment; continuous
use of anti-inflammatory drugs, symptomatic hip osteoarthritis and physiotherapeutic knee
treatment within the last 3 months.
All potentially eligible participants were contacted by telephone and those interested in
participating were invited to attend a physical examination for inclusion and exclusion
criterion. All participants were informed about the study and provided informed consent
before participating. They were assigned by block randomization, stratified according to
treatment group. An independent researcher not involved in outcome assessment was responsible
for group allocation, using a computer-generated random number table. Immediately after
baseline assessment by the blinded assessor, the treating physiotherapist accessed the
allocation schedule from a centrally located locked cabinet. Patients and the physiotherapist
responsible for the evaluation and physiotherapist responsible for the treatment were all
unaware of the randomization results as allocation to groups was concealed.
Demographic and anthropometric data, the use of pain relief medications, the duration of knee
pain, the knee range of motion, and a range of patient-reported outcomes were collected at
baseline (before randomization) and 8 weeks from baseline by the same blinded evaluator.
The primary outcomes were pain intensity measured by the numeric pain rating scale (0-10)
with a minimal clinically important change set at two points and disability measured using
the Lequesne questionnaire, which consists of 11 questions about pain, discomfort, and
function. Scores range from 0 to 24 (from 'no' to 'extremely severe' dysfunction).
Secondary outcomes included medication intake (Paracetamol) for knee pain relief, mobility
and balance, range of motion, muscular strength, and activity. Mobility and balance were
evaluated by the Timed Up and Go test. The Timed Up and Go test, a measure of functional
mobility, quantifies in seconds the time that the individual needs to stand up from a chair,
walk 3m, turn back toward the chair and sit down again. Range of motion of the knees was
measured with a universal goniometer (AESCULAP). Muscular strength was estimated at maximal
isometric force for the quadriceps, using a portable dynamometer (Lafayette, USA). Under
stabilized conditions, patients, sitting with knees flexed at 60 (measured by a goniometer),
were asked to extend the legs as far as they could. Three attempts were conducted, and the
mean value was obtained. Muscular strength was estimated at maximal isometric force for the
quadriceps, using a portable dynamometer. Under stabilized conditions, patients, sitting with
knees flexed at 10, 60 and 90 degrees (measured by a goniometer), were asked to extend the
legs as far as they could. Three attempts were conducted and the mean value was obtained.
Physical activity was measured using the Western Ontario and McMaster Universities
Osteoarthritis questionnaire, which is self-administered and measures pain, stiff joints, and
physical activity. Increased scores suggest decreased activity.
In this study, all patients had osteoarthritis of both knees, and in every patient both knees
were treated with the allocated treatment.
Participants in the Group I received Diadynamic currents associated to Exercise while the
Group II received only exercises three times a week for 8 weeks following initial assessment.
The group I, Diadynamic currents was performed with the following parameters: application of
the two-phase current and then the long-term one. Each current was applied for 4 minutes on
the medial and lateral sides of the knee.
All patients followed the same training program (Table 1). The intervention was divided into
Phase-1, Phase-2 and Phase-3 during eight weeks with three sessions a week. Each session
lasted 45 minutes:
- 10 minutes warming-up (treadmill, ergometer bike or rowing machine);
- 30 minutes 2-3 sets with Phase-1, Phase-2 and Phase-3;
- 5 minutes stretching (hamstrings, quadriceps, adductors, and gastrocmenius).
Participants were instructed not to use analgesic medications other than paracetamol
(500 mg/day) or anti-inflammatory drugs during the study, and not to perform any other
type of physical exercise in addition to the exercise performed during the study.
After describing the data, the hypothesis of normality of continuous variables was tested
using the Shapiro-Wilk test. The age, weight, height and BMI of volunteers between groups
were compared using Student's t-test for independent samples. To investigate the effect of
the treatment on the pre and post evaluation, as well as the interaction of this effect
between the groups, the General Linear Models with mixed design (evaluations x groups) were
applied. To analyze the effects of the interactions, Tukey's Post Hoc tests were performed
considering an alpha error of 5%. All analyzes were performed using the statistical program R
version 3.1.3 using the R Commander graphical interface.
