Low
power
laser
therapy
of shoulder tendonitis.
-
England S; Farrell AJ; Coppock JS; Struthers G;
Bacon PA
-
Scandinavian journal of rheumatology; VOL: 18 (6);
p. 427-31 /1989/
-
Department of Rheumatology, Coventry & Warwickshire
Hospital, UK.
30 patients with supraspinatus or bicipital
tendonitis were randomly allocated to active
infrared
laser
therapy
at 904 nm three times weekly for 2 weeks, dummy
laser
or drug treatment for 2 weeks. O
bjectively maximum active extension, flexion and
abduction of the shoulder, and subjectively pain
stiffness movement and function were measured at 0
and 2 weeks.
Significant improvement of active over dummy
laser
was noted for all seven assessments. Active
laser
therapy
produced significant improvement over drug
therapy
for all three objective measures and pain. Naproxen
sodium significantly improved only movement and
function compared to dummy
laser.
These results demonstrate the effectiveness of
laser
therapy
in tendonitis of the shoulder.
Laser
Treatment for Tendinitis
Jan M. Bjordal,
PT-MSc, Faculty of Medicine, University of Bergen,
Norway Christian Couppe, PT, Copenhagen, Denmark
Tendinitis is a
common disorder of the musculoskeletal system.
Cardinal symptoms from the tendon are pain from
increased tension like muscle contraction or
stretching and pain on pressure. In an acute stage
inflammation is the most common pathophysiological
manifestation, while degeneration of the collagen
structure is observed in subacute and chronic cases.
However, the episodic nature of chronic tendinitis
with increased pain after strenous use of the
affected tendon, may indicate that inflammation also
play a part at this stage. A succesful strategy of
treatment should include reduction of inflammation
and regeneration of collagen. In the laboratory
several experiments have shown that laser treatment
may have the potential to achieve both these goals.
The findings of the laboratory also shows that these
effects are highly dependent on dose.
A synthesis of dose from 4 laboratory
trials on inflamed collagen producing cell cultures
gives the following dose for optimal reduction of
tendon tissue inflammation:
Dose : 3 - 8 J/cm2
Intensity : 5 - 21 mW/cm2
A synthesis from 10 laboratory trials
investigating collagen proliferation gives the
following optimal dose for stimulation of tendon
regeneration :
Dose : 0.2 - 4 J/cm2
Intensity : 2 - 10 mW/ cm2
For the treatment of tendinitis an
optimal suggested dosage at target location will be
:
Dose : 0.2 - 4 J/cm2
Intensity : 2 - 10 mW/ cm2
Treatment should
be applied daily for at least five days to reduce
inflammation, and for at least 10 days to increase
collagen production.
Determination of
clinical dose
The clinical dose depends on several factors such as
laser type, depth to target from skin surface, the
type of tissue between skinsurface and target
location and the volume of injured tissue.
Characteristics for common tendon disorders
The various tendon locations have different
characteristics that affects determination of dose.
Tendon Depth to
target tendon (mm)
Tendon thickness (mm)
Typical area of tendon defect (cm2)
Values for
different conditions are as follows:
Plantar fasciitis
10.0 - 12.0
3.0 - 4.0
0.1 - 0.8
Achilles
1.5 - 3.0
4.5 - 6.0
0.5 - 2.0
Patellar
2.5 - 4.0
5.5 - 8.0
1.0 - 4.0
Epicondylitis
1.5 - 2.5
2.0 - 4.0
0.09 - 0.3
Rotatorcuff
5.0 - 10.0
5.5 - 8.0
0.5 - 1.5
Recommendations for optimal laser therapy for common
tendon disorders:
Infrared lasers (GaAlAs 820/830 nm) are recommended
when :
* Power density on skin does not exceed 30 mW/cm2,
when treating superficial disorders
* Spot size should not be smaller than 0.5 cm2
Dose on skin:
Number of points:Lateral epicondylitis :2 J/cm21 - 2
Rotatorcuff : 2.5 J/cm22 - 4 Patellar :8 J/cm2 :3 -
5Achilles :6 J/cm22 - 3
It must be added that there are only two clinical
trials showing effect on tendinitis (rotatorcuff)
with these lasers and that the dose recommendations
for other locations are extrapolations and have not
yet been tested clinically.
Infrared
pulse lasers (GaAs 904 nm) are recommended when :
* Power density on skin does not exceed 20 mW/cm2,
when treating superficial disorders
* Spot size should not be smaller than 0.5 cm2
Dose on skin:
Number of points:Lateral epicondylitis :0.5 - 2
J/cm2 1 - 2 Rotatorcuff : 0.8 - 6 J/cm2 2 - 4
Patellar :0.8 - 6 J/cm2 :3 - 5Achilles :0.5 - 4
J/cm2 2 - 3
Clinical results from seven trials suggests that
pulse lasers overcome the skin barrier with less
need for variation of dose for the different tendon
locations.
Red HeNe
lasers (632 nm) are only
recommended for superficially situated tendon
disorders like epicondyitis and paratendonitis of
the achilles or patellar tendon. Use of HeNe laser
on rotatorcuff, deeply situated patellar tendinitis
(jumpers' knee), plantar fascitis or carpal tunnel
is not recommended, due to the poor penetration of
visible red light.
Editors note:
The master thesis in Physiotherapy Science of Jan
Bjordal is called "Low Level Laser therapy in
shoulder tendinitis/bursitis, epicondylalgia and
ankle sprain. A critical review on clinical
effects". Division of Physiotherapy Science,
University of Bergen. 1997.
Part of this
thesis can be found in Physical Therapy Reviews.
1998; 3: 121-132. "What may alter the conclusions of
reviews?".
LOW LEVEL LASER THERAPY CAN BE
EFFECTIVE FOR TENDINITIS: A META-ANALYSIS
J.M. Bjordal, C. Couppe University
of Bergen, Dept. Physiotherapy Science, Bergen,
Norway
Purpose:
To investigate if low level laser therapy (LLLT)
with previously defined optimal treatment parametres
can be effective for tendinitis. Material :
Randomized controlled trials with LLLT for
tendinitis. Method : Literature search for
trials published after 1980 using LLLT on Medline,
Embase, Cochrane Library and handsearch of
physiotherapy journals in English and Scandinavian
languages. Only trials that compared laser exposure
of the skin directly over the injured tendon with
optimal treatment parametres with identical placebo
treatment were included.
Results: The literature search identified 77
randomized controlled trials with LLLT, of which 18
included tendinitis. Three trials were excluded for
lack of placebo control, of which one trial was
comparative, another lacked patients with tendinitis
in the treatment group, while the last unwittingly
gave the placebo group active treatment. Four trials
used too high power density or dose, and three
trials did not expose the skin directly overlying
the injured tendon. The remaining eight trials were
included in a statistical pooling, where the mean
effect of LLLT over placebo in tendinitis was
calculated to 32% [25.0-39.0, 95% CI].
Conclusion: Low level
laser therapy with optimal treatment procedure/parametres
can be effective in the treatment of tendinitis.
Low level laser therapy for
tendinopathy. Evidence of a dose-response pattern.
Physical Therapy Reviews.
2001; 6: 91-99.
Bjordal J M, Couppé C, Ljunggren E.
To investigate whether low-level laser therapy can
reduce pain from tendinopathy, the authors performed
a review of randomised placebo-controlled trials
with laser therapy for tendinopathy. Validity
assessment of each trial was done acc. to predefined
criteria for location-specific dosage and
irradiation of the skin directly overlying the
affected tendon.
The literature search identified 78
randomised control trials of which 20 included
tendinopathy. Seven trails were excluded for not
meeting the validity criteria on treatment procedure
and trial design. 12 of the remaining 13 trials
investigated the effect of laser therapy for
patients with subacute and chronic tendinopathy and
provided a pooled mean effect of 21%.
If results from only the nine trials
adhering to assumed optimal treatment parameters
were included, the mean effect over placebo
increased to 32%.
Laser therapy can reduce pain in
subacute and chronic tendinopathy if a valid
treatment procedure and location-specific dose is
used.
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