SA JOURNAL OF PHYSIOTHERAPY 2002 VOL 58 NO 2          15

ABSTRACT: Objectives: Muscle blood flow in the forearm of patients with rheuma-
toid arthritis and healthy volunteers following treatment with temperature increasing
arm baths, mudpacks and short- or decimeter-wave diathermy was studied in this
investigation. The aim of the study was to find out the difference of reactive 
hyperemia between the different temperature methods as well as the influence on the
consensual reaction.

Subjects: Eighty patients with rheumatoid arthritis, stage 3 according to
Steinbrocker, as well as 80 healthy human subjects had been assigned numerically in the four therapy- and control
groups. Patients with diseases influencing the peripheral blood flow were excluded.

Design: Blood flow was measured by venous occlusion plethysmography in both forearms with the subjects lying
supine. The application of the local heat therapies had been excluded on the left forearm. The forearm blood flow was
monitored before heat therapy, directly after as well as in two further 10 minutes intervals. An analysis of variance
was used to determine the influence on blood flow of the response to the heat therapies in patients with rheumatoid
arthritis and healthy subjects.

Results: Under homogeneous starting conditions and a statistically uniformed high blood flow in rest the reactive 
values of blood flow on the left-hand side of application and the right consensual side showed high significant differences
between all methods of therapy. Differences between the patients and the healthy subjects only showed tendencies with
partially lower reactions, concerning the patients with rheumatoid arthritis. All methods of heat therapy caused a 
statistically provable consensual reaction that turned out smaller after diathermic methods. Here the post therapeutic
reaction of the blood flow on the side of application was also lower or rather shorter.

Conclusion: Greater differences of the blood flow in rest between the patients with rheumatoid arthritis and healthy
subjects could not be observed. Temperature increasing arm baths and mud packs induced a provable higher increase
of local and consensual forearm blood flow than did diathermic methods. These results lead to the conclusion that
there are differences in temperature distribution between the methods of therapy. Increasing arm baths and mud packs
seem to have a stronger influence on the thermo reflexive skin perfusion.

KEY WORDS:  LOCAL HEAT THERAPY, MUSCLE BLOOD FLOW, PATIENTS WITH RHEUMATOID ARTHRITIS,
HEALTHY SUBJECTS.

BLOOD FLOW IN THE FOREARM IN PATIENTS
WITH RHEUMATOID ARTHRITIS AND HEALTHY
SUBJECTS UNDER LOCAL THERMOTHERAPY

MUCHA C1

1
Medizinische Rehabilitation und
Prevention, Deutsche Sporthochschule,
Köln.

CORRESPONDENCE TO:
C Mucha
Medizinische Rehabilitation und
Prevention Deutsche Sporthochschule 
Carl-Diem-Weg 6
D-50933 Köln
E-mail: mucha@dshs-koeln.de

R E S E A R C H
A R T I C L E

INTRODUCTION
Although local heat treatment is often
applied in patients with rheumatoid
arthritis (RA), there are only few inves-
tigations (Mucha, 1998) on the effect of
thermotherapy on peripheral blood flow.
Such investigations are usually carried
out in healthy subjects (Silverman and
Pendleton, 1968; Wessmann, 1971).
Oka et al (1971) investigated muscle
blood flow in RA patients without cli-
nical manifestations of vascular disease
and observed a reduced resting blood
flow with simultaneous intensification
of the ischaemic reaction. Betz (1955)
described a more intense warming reac-

forearm of RA patients and healthy
subjects? 

• What is the consensual reaction of 
the contralateral arm?

• What differences are present in 
reactive blood flow between the 
thermotherapies applied?

tion to temperature stimuli in patients
with rheumatoid arthritis than in healthy
subjects. In occasional cases, vascular
lesions have also been described. Their
potential role in the pathogenesis of
rheumatoid arthritis has been discussed
(Skrifvars et al 1969; Bowman et al
1975; Rothschild and Masi, 1982). 

The following questions were to be
investigated in the present study:
• What blood flow reactions result 

after application of various local 
thermotherapies (rising-temperature
arm bath, parafango pack, short-wave
27,12 MHz/11m and decimeter-wave
433,92 MHz/ 69 cm treatment) on the



16          SA JOURNAL OF PHYSIOTHERAPY 2002 VOL 58 NO 2

TEST SUBJECTS
Eighty patients with rheumatoid arthritis
in stage 3 according to Steinbrocker
(1949) and the same number of healthy
test subjects were numerically allocated
to eight comparison groups each com-
prising four treatment groups. The lack
of an acute inflammatory episode, heart
diseases not requiring treatment and
polyneuropathies as well as normoten-
sive blood pressure values were further
inclusion criteria. In the healthy control
groups, age classes and sex distribution
were matched to the RA groups. All test
subjects were instructed concerning the
investigation procedure and method of
measurement.

METHODS
The investigation took place in a labora-
tory with constant ambient temperature
of 23 - 24˚C, a relative humidity of 
36 - 38% and always at the same time 
of day. After an initial 20 minutes rest
phase measurements and treatment took
place in the supine position of the test
subjects. In one patient group (n=20)
and a test subject group (n=20) one of
these thermotherapies was administered:
rising-temperature arm bath, parafango
wraps, short-wave diathermy, decimeter
wave irradiation. The applications were
carried out on the left side and for all
modalities 15 minutes long.

The arm bath was carried out in a
tube bath. The application started at the
thermoneutral zone of 36˚C. For the
next 15 minutes of application the 
temperature was raised successively up
to 44 - 45˚C adjusted by a thermostatic
inflow. The parafango wrap was 4cm
thick and was prepared at a temperature
of 55˚C. After cooling down the surface
to a tolerated temperature it was applied
to the entire forearm from wrist to
elbow. Short-wave diathermy was
applied with a diplode at dose level 4.
The Ultratherm(r) instrument (firm:
Siemens) was used. For the decimeter
wave irradiation the Siretherm(r) 
instrument (firm: Siemens) was taken.
The round-field emitter was placed over
the forearm at a distance of 5cm at a
power level of 4 = 80 watts.

Forearm blood flow was measured
with venous occlusion strain gauge
plethysmography simultaneously on

both arms before application of heat,
immediately afterwards as well as 10
and 20 minutes later. Position and 
application conditions were maintained
in accordance with the recommen-
dations of Graf (1964). The Periquant
3800 (firm: Gutman(r)) instrument used
for blood flow registration automatically
evaluated the volume fluctuations and
expressed them as ml/100 ml tissue 
per minute.

STATISTICAL ANALYSIS
The blood flow values obtained at the
defined measurement times were
recorded. After completion of the mea-
surement series, the data were subjected

to statistical analysis together with the
demographic data of the test subjects 
as well as the anamnestic data of the
patients. The statistical package of social
sciences (SPSS) program system was
used. For descriptive statistics, the data
were broken down into initial and
progress criteria and their absolute 
and relative incidences were compared.
Multivariate analyses of variance were
calculated for the group comparison
over time. Univariate analyses of vari-
ance were considered in significant F
statistics. The Newman-Keuls test was
used to compare group differences. The
chi-square test served as a test of homo-
geneity for the evaluation for qualitative

25

20

15

10

  5

  0
  rest after therapy 10 min. after therapy 20 min. after therapy

[time in min]

[m
l/

1
0
0
m

l*
m

in
]

RA patients – right side

x x
x

decimeter wave

  mudpack

increasing arm bath

short wave

Figure 1: Forearm blood flow after application of the different methods of thermo-
therapy in the patient groups (n = 20).

25

20

15

10

  5

  0
  rest after therapy 10 min. after therapy 20 min. after therapy

[time in min]

[m
l/

10
0m

l*
m

in
]

healthy candidates – right side

x
x

x
decimeter wave

  mudpack

increasing arm bath

short wave

Figure 2: Forearm blood flow after application of different forms of thermotherapy in
the healthy reference groups (n = 20).



SA JOURNAL OF PHYSIOTHERAPY 2002 VOL 58 NO 2          17

and group semiquantitative initial data
in contingency tables. The t-test was used
to compare two linked random samples.
The probabilities of error of 5% (p < 0.05)
and 1% (p< 0.01) were laid down as 
significant levels.

RESULTS
The age range in the overall population
of the RA patients was 51 - 60 years.
The average age interval of manifestation
of rheumatoid arthritis was 6 - 10 years.
The distribution of these features did not
show any statistically significant differ-
ences in the individual groups com-
pared. The age and sex distribution was
also homogeneous between the groups

of RA patients and healthy test subjects. 
The blood flow values on the left

(application) side in the therapy groups
of RA patients and healthy test subjects
at the defined measurement times are
shown in Figures 1 and 2. The values of
the contralateral side are shown in
Figures 3 and 4. The initial values
between 3.8 and 4.3 ml/100 ml tissue
per minute in RA patients on the left and
between 3.9 and 4.3 ml/100 ml tissue
per minute on the right and in healthy
subjects between 3.9 and 4.3 ml/100 ml
tissue per minute on the left and 4.0 and
4.3 ml/100 ml tissue per minute on 
the right, do not show any significant
differences. 

After application of thermotherapies,
however, the forearm blood flow also
shows a highly significant difference 
in the course between the methods of
treatment employed (F9,682 = 267.824;
p= 0,00). The post therapeutic reaction
values of the blood flow between the
patient and healthy subject groups are
also different. This also applies to the
comparison between the application 
side and the consensual changes in
blood flow on the contralateral side
(F1,54 = 54.868; p= 0,00). With isolated
consideration of the blood flow reac-
tions after rising-temperature arm bath
and parafango packs, these do not differ
between the patient and test subject
groups up to ten minutes after applica-
tion. The reactive blood flow in the RA
patients remains demonstrably higher
than in the healthy subjects only 20 
minutes after application of the parafango
packs. The consensual reaction after the
parafango pack also only shows slight
differences compared to the application
side both in the patient and in the test
subject group. The blood flow reactions
after application of the diathermy method
(short-wave 27,12 MHz/11m and deci-
meter-wave 433,92 MHz/69cm) show
largely comparable interrelationships in
their chronological development and 
in the consensual reaction. Apart from
the rise in blood flow immediately after
application of the decimeter wave to 
the left side in healthy subjects, we
attained an equally high level over time
to that after rising-temperature arm bath.
The reaction values of both high-
frequency methods are significantly
lower than those after parafango packs
and rising-temperature arm bath. It is
noticed that after application of deci-
meter waves, the highest blood flow
reaction was immediately after applica-
tion, whereas it was only 10 minutes
later in short-wave therapy. The consen-
sual reaction is very much less with 
both methods and is likewise only
unequivocally demonstrable immediately
after application of decimeter wave
treatment. Very much higher reaction
values were also attained in the healthy
test subjects than in the RA patients on
the left (application) side. Tables 1 and 2
summarize the post therapeutic mean
value comparisons between the thermo-

25

20

15

10

  5

  0
  rest after therapy 10 min. after therapy 20 min. after therapy

[time in min]

[m
l/

10
0m

l*
m

in
]

RA patients – left side

x

x x
decimeter wave

  mudpackincreasing arm bath

short wave

Figure 3: Consensual blood flow reaction in the contralateral forearm after the 
individual thermotherapies in the patient groups (n = 20).

25

20

15

10

  5

  0
  rest after therapy 10 min. after therapy 20 min. after therapy

[time in min]

[m
l/

10
0m

l*
m

in
]

healthy candidates – left side

decimeter wave

  mudpack

increasing arm bath

short wave

x

x

Figure 4: Consensual blood flow reaction in the contralateral forearm after the 
individual thermotherapies in the healthy references groups (n = 20).



18          SA JOURNAL OF PHYSIOTHERAPY 2002 VOL 58 NO 2

therapy methods at the defined times 
of measurement on the application side.
The corresponding values for the 
contralateral forearm are shown in
Tables 3 and 4. 

DISCUSSION
Venous occlusion plethysmography is a
recognized, readily reproducible method
of measurement for quantitative detec-
tion of segmental blood flow charac-
teristics (Greenfield, 1960; Altenkirch et
al 1989; Le Jemtel et al 1992).

However, the resting blood flow is
especially dependent on external influ-
ences so that the test must be conducted
in accordance with the recommen-
dations by Graf (1964) in order to 
minimize these external influences. In
this study, these recommendations include
the observations of prior rest phases,
positioning criteria, acclimatization,
constant times of day. Resting blood
flow in the forearm is reported to be
between 3 and 5 ml/100 l tissue per
minute in the literature (Bollinger, 1965;
Altenkirch et al 1989; Joyner et al 1990).
In this investigation, it was between 
3.8 and 4.3 ml/100 ml tissue per minute.
Differences between the patient and test
subject groups and the lateral location
were very small and could not be 
detected statistically. On the other hand,
Oka et al (1971) found lower resting 
values and a more intense reactive
hyperemia after ischemic stasis in RA
patients compared to healthy subjects.
Although they used the clearance
method, the divergencies from the 
present results cannot necessarily be
explained by the technique of measure-
ment. It is more likely that the patient
groups were not directly comparable,
since Oka et al (1971) carried out the
investigations in patients with manifest
swelling in adjacent joints. In a further
comparison, they observed that it is 
crucially affected by the soft-tissue con-
ditions described. They did not observe
dependence of blood flow on parameters
of rheumatoid arthritis activity, duration
of the disease or age of the patients.
These variables were homogeneously
distributed in the reference populations,
so that they do not have to be taken 
into consideration for the cause of the
reaction after local heat application. It is

Table 1: Mean value comparisons (Newman-Keuls-test) of the post therapeutic reaction
of circulation on the application side within the patients’ collectives.

Immediate Post Therapy
Method Short-Wave Parafango Decimeter Incr. Arm 

Wave Bath
7,06 8,00 10,19 13,96

±s 0,99 1,17 1,16 1,73
Parafango (p) 3,56 (0,05)
Decimeter wave (p) 11,92 (0,01) 8,36 (0,01)
Incr. arm bath (p) 26,31 (0,01) 22,75 (0,01) 14,38 (0,01)

10 Minutes After Therapy
Method Decimeter Short-Wave Parafango Incr. Arm

Wave Bath
5,36 7,36 13,63 17,95

±s 0,95 1,47 1,54 2,26
Short-wave(p) 7,51(0,01)
Parafango (p) 31,11 (0,01) 23,59 (0,01)
Incr. arm bath (p) 47,34 (0,01) 39,82 (0,01) 16,23 (0,01)

20 Minutes After Therapy
Method Decimeter Incr. Arm Short-Wave Parafango

Wave Bath
4,27 4,35 6,87 9,80

±s 0,93 0,86 0,70 2,05
Incr. arm bath (p) 0,29
Short-wave(p) 9,90 (0,01) 9,61 (0,01)
Parafango (p) 21,07 (0,01) 20,77 (0,01) 11,16 (0,01)

Table 2: Mean value comparisons (Newman-Keuls-test) of the post therapeutic reaction
of circulation on the application side within the healthy collectives.

Immediate Post Therapy
Method Short-Wave Parafango Decimeter Incr. Arm 

Wave Bath
7,99 9,78 13,91 14,14

±s 1,16 1,15 1,55 1,71
Parafango (p) 6,86 (0,01)
Decimeter wave (p) 22,59 (0,01) 15,73 (0,01)
Incr. arm bath (p) 23,45 (0,01) 16,59 (0,01) 0.85

10 Minutes After Therapy
Method Decimeter Short-Wave Parafango Incr. Arm

Wave Bath
7,49 9,19 15,30 17,98

±s 1,33 1,43 1,92 2,13
Short-wave(p) 6,47 (0,01)
Parafango (p) 29,74 (0,01) 23,26 (0,01)
Incr. arm bath (p) 39,97 (0,01) 33,49 (0,01) 10,22 (0,01)

20 Minutes After Therapy
Method Decimeter Short-Wave Incr. Arm Parafango

Wave Bath
4,20 6,02 7,38 7,51

±s 1,17 1,11 1,46 1,45
Short-wave(p) 6,95 (0,01)
Incr. arm bath (p) 12,13 (0,01) 5,18 (0,01)
Parafango (p) 12,63 (0,01) 5,67 (0,01) 0.49 (0,01)

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SA JOURNAL OF PHYSIOTHERAPY 2002 VOL 58 NO 2          19

a matter of discussion as to what 
extent the differences in resting blood
flow described by Oka et al (1971) and
Bowman et al (1975) result from differ-
ences attributable to vascular disorders
in RA patients. For example, Bollinger
(1965) attaches no functional diagnostic
importance to resting blood flow.

On the other hand, reactive hyperemia
results evidently reflect the functional
capacity and efficiency of the vessels
after arterial stasis or after muscular
exercise (Bollinger, 1965; Joyner et al
1990; Le Jemtel et al 1992). The reactive
blood flow values after application of 
all four thermotherapies in this investi-
gation show distinct differences from
resting blood flow and in the time 
course of the post therapeutic control
intervals. The progress differences
between the forms of therapy are signi-
ficant (F9,682 = 267.824; p= 0,00). This
applies both to the left (application) side
and to the right (consensual) side. The
reactive rise after rising-temperature
arm bath is greater than after parafango
packs, and both exceed the rises
observed after diathermy techniques.
The one exception is the blood flow
value obtained immediately after appli-
cation of decimeter wave irradiation.
Moreover, the blood flow reaction per-
sists for the shortest time and the 
consensual reaction is least pronounced
in the case of decimeter wave irradia-
tion. However, the raised blood flow
persists for 20 minutes after application
of short waves, although there is no 
discernible tendency to reduction in the
RA patients even then, in contrast to 
the effect observed in the healthy test
subjects. It is probable that the greater
concomitant warming of the skin/sub-
cutaneous tissue by the short wave is
responsible for this effect. 

Since the plethysmographic mea-
surements simultaneously register blood
flow in skin and muscle, the especially
high increases in blood flow after rising-
temperature arm bath and parafango
packs may be due to a greatly increased
blood flow in the skin. Besides intense
direct warming, both forms of therapy
lead to stimulation of the thermorecep-
tors in the skin, so that besides the 
direct effect of heat, an additional neu-
roreflex vascular reaction can be assumed

Immediate Post Therapy
Method Decimeter Short-Wave Parafango Incr. Arm 

Wave Bath
6,04 6,93 8,73 12,05

±s 1,15 1,01 1,27 1,77
Short-wave (p) 3,39 (0,05)
Parafango (p) 10,25 (0,01) 6,86 (0,01)
Incr. arm bath (p) 22,92 (0,01) 19,53 (0,01) 12,67 (0,01)

10 Minutes After Therapy
Method Decimeter Short-Wave Incr. Arm Parafango

Wave Bath
5,12 7,08 9,45 14,89

±s 0,89 0,99 1,14 1,56
Short-wave (p) 7,59 (0,01)
Incr. arm bath (p) 16,76 (0,01) 9,16 (0,01)
Parafango (p) 37,85 (0,01) 30,25 (0,01) 21,08 (0,01)

20 Minutes After Therapy
Method Decimeter Short-Wave Incr. Arm Parafango

Wave Bath
4,05 5,35 5,53 7,29

±s 0,18 0,94 1,34 1,31
Short-wave (p) 4,97 (0,01)
Incr. arm bath (p) 5,64 (0,01) 0,66
Parafango (p) 12,34 (0,01) 7,37 (0,01) 6,70 (0,01)

Table 4: Mean value comparisons (Newman-Keuls-test) of the consensual reaction of
the circulation at defined intervals within the healthy collective.

Immediate Post Therapy
Method Short-Wave Decimeter Parafango Incr. Arm 

Wave Bath
5,31 5,36 7.08 9.45

±s 0,97 0,91 1,00 1,14
Decimeter wave (p) 0,19
Parafango (p) 6,74 (0,01) 6,55 (0,01)
Incr. arm bath (p) 15,77 (0,01) 15,58 (0,01) 9,03 (0,01)

10 Minutes After Therapy
Method Decimeter Short-Wave Incr. Arm Parafango

Wave Bath
4,28 5,84 7,82 12,93

±s 0,95 1,73 1,21 1,60
Short-wave (p) 6,04 (0,01)
Incr. arm bath (p) 13,74 (0,01) 7,69 (0,01)
Parafango (p) 33,55 (0,01) 27,50 (0,01) 19,81 (0,01)

20 Minutes After Therapy
Method Incr. Arm Decimeter Short-Wave Parafango

Bath Wave
4,04 4,06 4,27 8,19

±s 0,17 0,17 0,89 1,50
Decimeter wave (p) 0,07
Short-wave (p) 0,85 0,78
Parafango (p) 15,81 (0,01) 15,74 (0,01) 14,96 (0,01)

Table 3: Mean value comparisons (Newman-Keuls-test) of the consensual reaction of
the circulation at defined control intervals within the patients’ collectives.

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20          SA JOURNAL OF PHYSIOTHERAPY 2002 VOL 58 NO 2

(Peters et al 2000). This evidently led 
to the greater increase of blood flow.
Results of Onabanjo (1978) showed 
that the warming of the sweat glands
already leads to an enzymatically induced
kininogen vasodilatation in the skin.
This is moreover intensified by the
effect of temperature on vasodilatory
nerves. This interpretation is also sup-
ported by the vigorous consensual reac-
tion which was attained under these
forms of treatment. This fact as well as
the comparatively smaller areas of
application with the diathermy tech-
nique caused by technical factors could
also explain their lower blood flow 
reactions, which would however also
indicate a more direct warming of the
musculature. Presupposing that there
was dystrophy of the forearm muscu-
lature due to RA in patients in an
advanced stage of the disease with a
long period of manifestation, the greater
blood flow reaction attained in the
healthy patients with the diathermy
technique can also be seen in this 
context. The characteristics of the blood
flow reactions over time after appli-
cation of decimeter waves also supports
the assumption that it is mainly muscle
blood flow which is affected in the
diathermy technique, since decimeter
waves lead to an even more specific
warming of the musculature than short
wave therapy.

According to Lehmann et al (1974)
an increase in temperature to 40˚C 
must be exceeded in order to attain a 
significant vasodilatation; moreover,
this temperature must be maintained for
three to five minutes. The blood values
of the reactive blood flow attained in
this investigation indicate that this 
temperature threshold was exceeded.

The influence of all four methods of
treatment on the rise of forearm blood
flow could be demonstrated. These
results have time-course characteristics
specific to the form of therapy up to 20
minutes after application. At the same
time, they bring about a consensual
reaction on the contralateral side. The
rising-temperature arm bath and para-
fango packs lead to a greater increase of
blood flow both on the application side
and consensually than the diathermy
techniques. Owing to the lack of differ-

entiation between muscle and skin blood
flow due to the techniques of measure-
ment it may be assumed that their 
higher reaction values are brought about
by a greater concomitant reaction of
blood flow in the skin. The blood flow
values attained after the diathermy 
techniques employed evidently repre-
sent mainly changes in muscle blood
flow which are accompanied by a less
pronounced consensual reaction. Diffe-
rences between RA patients and healthy
subjects could only be demonstrated 
in part and if anything as a tendency.
Since they also represent the therapy-
specific pattern of heat distribution, it
may be assumed that they are a result of
lower muscle volumes specific to 
the disease in RA patients and are less
attributable to functional restrictions of
the blood vessel that were referred to
above all by Skrifvars et al (1969), Oka
et al (1971) and Bowman et al (1975). 

Of all four thermotherapies rising-
temperature arm baths caused the highest
rise in blood flow followed by para-
fango wraps and decimeter wave irra-
diation. A comparably small rise in
blood flow was registered after short-
wave application. After both short wave
therapy and parafango wraps the increase
of blood flow was still detectable even
20 minutes after therapy though. This
indicates a longer distribution of heat
after those thermotherapies. The greatest
consensual reaction was caused by 
the rising-temperature arm bath imme-
diately afterwards. Parafango wraps
showed the greatest consensual reac-
tion ten minutes later. No significant
consensual reaction was recorded for
decimeter wave irradiation. Consequently
decimeter wave diathermy causes selec-
tive muscular warming.

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