Effect of physical training on fat-free mass in patients with chronic obstructive pulmonary disease 


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Upsala Journal of Medical Sciences

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Effect of physical training on fat-free mass in
patients with chronic obstructive pulmonary
disease (COPD)

Margareta Emtner, Runa Hallin, Ragnheiður Harpa Arnardottir & Christer
Janson

To cite this article: Margareta Emtner, Runa Hallin, Ragnheiður Harpa Arnardottir & Christer
Janson (2015) Effect of physical training on fat-free mass in patients with chronic obstructive
pulmonary disease (COPD), Upsala Journal of Medical Sciences, 120:1, 52-58, DOI:
10.3109/03009734.2014.990124

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Upsala Journal of Medical Sciences. 2015; 120: 52–58

ORIGINAL ARTICLE

Effect of physical training on fat-free mass in patients with chronic
obstructive pulmonary disease (COPD)

MARGARETA EMTNER1,2, RUNA HALLIN1, RAGNHEIÐUR HARPA ARNARDOTTIR1,3,4 &
CHRISTER JANSON1

1Department of Medical Sciences, Respiratory, Allergy and Sleep Research, Uppsala University, Uppsala, Sweden,
2Department of Neuroscience, Physiotherapy, Uppsala University, Uppsala, Sweden, 3School of Health Sciences,
University of Akureyri, Akureyri, Iceland, and 4Department of Rehabilitation, Akureyri Hospital, Akureyri, Iceland

Abstract
Background. Weight loss and depletion of fat-free mass are common problems in patients with chronic obstructive pulmonary
disease (COPD) and are related to muscular weakness and exercise intolerance. Physical training of COPD patients has good
effect on exercise tolerance and quality of life. The aim of this study was to examine factors that affect change in fat-free mass
after physical training, in patients with COPD.
Patients. Patients were examined before and after a 4-month exercise period. Weight and height were measured, and
bioelectrical impedance was performed. Fat-free mass (FFM) was calculated, by a three-compartment model, and fat-free
mass index (FFMI) was calculated as FFM kg/m2 and body mass index (BMI) as kg/m2. A symptom-limited ramp ergometer
test and 12-minute walk test (12MWT) were performed. Dyspnoea score of daily activities was determined by Chronic
Respiratory Disease Questionnaire (CRDQ). Blood was taken for analyses of C-reactive protein (CRP) and fibrinogen.
Patients with a BMI <21 kg/m2 were given nutritional support during the training period.
Results. A total of 27 patients completed the training (64 years, FEV1 31% of predicted). Patients with low FFMI gained 1.2 kg,
whereas those with normal FFMI lost 0.7 kg (p = 0.04). In multivariate analyses high age (p = 0.03), low FEV1 (p = 0.02), and a
high level of dyspnoea (p = 0.01) at baseline were found to be negative predictors for increase in FFM.
Conclusions. Difficulties in increasing the fat-free mass in COPD patients by physical training seem to be associated with
dyspnoea in daily life and impaired lung function (FEV1).

Key words: Chronic obstructive pulmonary disease, dyspnoea, exercise training, fat-free mass, nutrition

Introduction

There is growing evidence that chronic obstructive
pulmonary disease (COPD) is a multi-organ systemic
disease. Skeletal muscle weakness, muscle wasting,
and impaired exercise performance, which are poorly
related to air flow limitation, have commonly been
reported in COPD patients (1).
Exercise-limiting factors include muscular weak-

ness (2), dynamic hyperinflation resulting in increased
work of breathing (3), increased load on the respira-
tory muscles (4), and an intensified perception of

respiratory discomfort. In addition, symptoms per-
ceived by the patients with anxiety and depres-
sion have impact on training tolerance and physical
activity (5).
Loss of body weight is a common and serious

finding in patients with COPD (6) and is associated
with increased mortality and morbidity independent of
gender, smoking, and lung function (7). Patients with
low fat-free mass (FFM) often have muscular weak-
ness, especially in the lower limbs (8). Low weight is
also related to low health-related quality of life and
worsening dyspnoea (9).

Correspondence: Margareta Emtner, Department of Medical Sciences, Respiratory, Allergy and Sleep Research, Uppsala University, Uppsala, Sweden.
E-mail: margareta.emtner@neuro.uu.se

(Received 13 October 2014; accepted 17 November 2014)

ISSN 0300-9734 print/ISSN 2000-1967 online � 2014 Informa Healthcare
DOI: 10.3109/03009734.2014.990124

http://informahealthcare.com/journal/ups
mailto:margareta.emtner@neuro.uu.se


Pulmonary rehabilitation is an important compo-
nent in the management of subjects with COPD (10)
and is effective in improving exercise performance and
health status (10). Exercise training is a core compo-
nent of pulmonary rehabilitation and has been shown
to be the best available means of improving muscle
function, exercise capacity, and cardiovascular func-
tion (10). Exercise training has also been shown to
result in less dyspnoea in daily life (11) and to less
mood disturbance. Before training start, an adequate
assessment including evaluation of body composition,
i.e. FFM, needs to be performed in order to optimize
intervention strategies (10). Body mass index (BMI) is
a simple way to assess body composition. However, it
is possible to have normal BMI and still be nutrition-
ally depleted (12). FFM reduction is a better predictor
of peak exercise performance than BMI (13), and it
has been suggested that FFM is the best parameter to
assess body composition.
A few studies have investigated the efficacy of

multimodal intervention, including nutrition and ana-
bolic steroids integrated into pulmonary rehabilitation
for advanced COPD patients (14-16). Although the
intervention was successful in improving body weight,
FFM, and exercise tolerance, the influence of the
various components could not be determined.
The underlying mechanisms contributing to deple-

tionofskeletalmusclestillremainunclear.Associations
between various circulating markers of inflammation
and the loss of muscle mass have been made in chronic
inflammatory disease conditions, including COPD.
The aim of this study was to examine factors that

affect change in fat-free mass after a period of physical
training, in patients with COPD.

Material and methods

The study population was recruited from patients
included in an exercise study comparing different
training methods (17). Patients with moderate to
severe COPD, according to the Global Initiative for
Obstructive Lung Disease (GOLD) criteria, were
consecutively invited to participate in the exercise
study (1). Inclusion criteria were COPD with a
post-bronchodilator FEV1/FVC ratio <0.7 and a
FEV1 <60% of the predicted value. All patients
(n = 51) included in the training study were asked
if they wanted to participate in the current study.
Forty-nine patients (96%) agreed to participate, of
whom 27 patients completed the 4-month training
period. Patients were considered drop-outs if they
attended less than 75% of the training sessions.
Reasons for drop-out were exacerbations (n = 16),
other diseases (n = 2), and lack of motivation or
transportation problems (n = 4).

Measurements were made before and after the
4-month training period. Information on smoking
historywasobtainedusingastructuredinterview.Infor-
med consent was obtained from all the participants.

Exercise training

Exercise sessions were performed twice a week. Each
session included cycle ergometer training at an inten-
sity ‡65% of baseline peak exercise capacity (Wpeak)
for 27 min. For warming up (6 min) and cooling
down (6 min) the patients cycled at 30%–40% of
baseline Wpeak. After the cycling, once a week the
session proceeded with flexibility and relaxation train-
ing, while the other session of the week proceeded
with resistance training for upper and lower limbs as
well as abdominal muscles (10 repetitions, two sets at
about 70% of 1 repetition maximum). Exercise load
was kept as high as tolerated at all times, above the
target value when possible. Patients who desaturated
on exercise (SpO2 <90%) were given supplemental
oxygen during training to keep SpO2 ‡90%. All
patients with BMI <21 kg/m2 were given nutritional
support ad libitum. The threshold of 21 kg/m2 was
chosen because mortality has been shown to be
increased below this value in COPD populations (18).

Body composition

Body height was measured to the nearest 0.5 cm, and
weight was measured on a balance scale to the nearest
0.1 kg. Bioelectrical impedance analysis was per-
formed in the morning with patients in a fasting state
using a Hydra EFC/ICF, model 4200, Xitron Tech
(San Diego, CA, USA). FFM was calculated by a
three-compartment model, and the fat-free mass
index (FFMI) was calculated as FFM kg/body height
m2 and BMI as kg/m2. Limits for depleted FFM were
employed: FFMI £16 kg/m2 was used for men and
£15 kg/m2 for women. The two outcome variables
used were change in FFM, and FFM in per cent of
baseline values (change in FFM of baseline).

Physical capacity

Peak exercise capacity in watt (Wpeak) was determined
by a progressive symptom-limited cycle ergometer
test (Case 8000 Exercise Testing System, GE Medical
Systems, Milwaukee, WI, USA).
Functional exercise capacity was measured by the

self-paced 12-min walk test (12MWT) (19). The
walking tests were performed in a level corridor,
and the total distance walked (in meters) was mea-
sured. Two tests were performed both before and
after the training period. The second test was repeated

Factors associated with change in fat-free mass in COPD 53



on a different day within one week. The better of the
two tests was used.

Dyspnoea

For evaluation of dyspnoea during activities in daily
life the dyspnoea scale from the Chronic Respiratory
Disease Questionnaire (CRDQ) was used (20).
Patients scored dyspnoea experienced during five
self-chosen activities of daily living. The scale for
each of the five activities is 7-graded, and a higher
score indicates less dyspnoea. The score from the five
activities were combined, and the combined dyspnoea
score thereby ranged from 5 to 35.

Systemic inflammation

Blood samples were taken for analyses of C-reactive
protein (CRP) and fibrinogen. High-sensitivity CRP
was measured with a two-point nephelometry method
with a ProSpec instrument (Dade Behring, Marburg,
Germany) using monoclonal mouse antibodies (Dade
Behring, Marburg, Germany). The total analytical
imprecision was 1.4% at 1.23 and 5.49 mg/L, with
a lowest detectable level of 0.17 mg/L.
Measurement of fibrinogen was performed using

a ProSpec instrument (Dade Behring, Marburg,
Germany) with a rabbit antibody against fibrinogen
(Dade Behring, Marburg, Germany). The total analyt-
icalimprecisionwas5.7%at2.2g/Land4.4%at4.7g/L.
Analyses were carried out at the Department of

Clinical Chemistry at Uppsala University Hospital,
Sweden.

Lung function

Forced expiratory volume in one second (FEV1) was
measured with a Jaeger master scope Spirometer
(Jaeger, Höchberg, Germany). The best of three
acceptable manoeuvres was used in accordance
with the American Thoracic Society guidelines for
standardization of spirometry (21). FEV1 was expres-
sed as a percentage of the predicted value using
Swedish reference values (22,23).
The Ethics Committee at the Medical Faculty at

Uppsala University approved the study (2002-07-02,
Dnr 02-307).

Statistics

Results are expressed as mean ± SD. Spearman rank
correlation and multiple linear regression analysis
were used when analysing the relation between
change in FFM expressed in absolute values and
per cent of the baseline values and baseline

characteristics. Spearman rank correlation was also
used when analysing association between change in
FFM and change in 12MWT and Wpeak. Variables
associated with change in FFM at p < 0.10 in bivariate
analyses were included in the multiple linear regres-
sion model. CRP was log-transformed before being
entered into the analyses. Statistically significant
difference was assumed when p < 0.05.

Results

The study included 27 patients who completed the
4-month physical training period. The attendance rate
was 29 ± 3 of 32 possible sessions. Patients with low
FFMI at training start were more likely to gain weight
than patients with normal FFMI (Table I). Nutritional
supplementation during the exercise training period
was given to all patients with BMI below 21 kg/m2 at
baseline; this meant that most patients with low FFMI
received supplementation, whereas none of the
patients with normal FFMI received supplementation
(Figure 1).
The median change in FFM was 0.6 kg, while the

median change in 12MWT and Wpeak was 54 m and
10 W, respectively (Figure 2). Statistically significant
correlations were found between changes in FFM and
FEV1, FFMI, dyspnoea score, and fibrinogen at
baseline (Table II). There were no significant associa-
tions between change in FFM and change in 12MWT
or change in Wpeak.
Inthe multivariate analyses approximately 70% ofthe

variation in FFM change was accounted for when age,

Table I. Baseline characteristics and changes in body composition
and physical capacity, for patients with low or normal fat-free mass
index (FFMI). Low was defined as FFMI £16 kg/m2 for men and
£15 kg/m2 for women.

Low FFMI
(n = 15)

Normal FFMI
(n = 12) p

Female (%) 48 26 0.09

Age (years) 64 ± 7 65 ± 7 0.73

FEV1 % predicted 32 ± 10 31 ± 11 0.68

Fibrinogen (mg/L) 4.1 ± 1 3.9 ± 1 0.71

CRP (mg/L) 6.5 ± 10.1 8.2 ± 11.5 0.70

Pack-years 40 ± 9 40 ± 9 0.94

Dyspnoea score 17 ± 4 17 ± 3 0.90

D Weight (kg) 1.2 ± 2.4 –0.67 ± 2.1 0.04

D Fibrinogen (mg/L) –0.3 ± 0.9 –0.1 ± 0.8 0.53

D CRP (mg/L) –4.4 ± 10.9 –1.4 ± 12.9 0.58

D FFM (kg/m2) –0.2 ± 2.4 1.3 ± 1.6 0.07

D Wpeak (watt) 20 ± 28 11 ± 10 0.40

D 12MWT (m) 99 ± 90 35 ± 66 0.06

54 M. Emtner et al.



sex,FEV1,dyspnoea,andfibrinogenwerecombinedina
multiple regression model (Table III). Change in FFM
was negatively correlated with age and positively with
FEV1 and a higher dyspnoea score indicating less
dyspnoea at the start of the training period.

Discussion

Our main finding is that patients with lower age,
higher FEV1, and a lower level of dyspnoea were
more likely to increase in muscle mass during a
4-month physical training period.
Moreover, patients with a low FEV1 were less likely

to increase in FFM. It has been shown that muscle
strength and FEV1 are factors limiting exercise

capacity (2), and that expiratory airflow obstruction
is a limiting factor to maximal ventilation and thereby
limits exercise tolerance (24). There are multiple
possibilities for the association between airflow
obstruction and exercise limitation, for example
dynamic hyperinflation (3) resulting in increased
work of breathing, increased load on the respiratory
muscles (4), and the intensified perception of respi-
ratory discomfort. Another possible reason is that a
low FEV1 is related to hypoxic muscles due to insuf-
ficient oxygen caused by insufficient blood supply or
hypoxemia (25).
We found that dyspnoea was a risk factor for not

increasing FFM during an exercise programme. One
recent study reported that dyspnoea on exertion is
correlated with general anxiety, indicating that exer-
cise training may be influenced negatively by anxiety-

–10

–7.5

–5

–2.5

0

2.5

5

7.5

10

12.5

15

Δ FFM % of baseline

Low FFMI kg/m2

at baseline
Normal FFMI
kg/m2 at baseline

Figure 1. Changesinfat-freemass(FFM)inpatientswithlowfat-free
mass index (FFMI) and normal FFMI between baseline and four
months of training. Low FFMI is defined as FFMI £16 kg/m2 for men
and £15 kg/m2 for women. Filled-symbols = patients given no supple-
mentation; open symbols = patients given supplementation.

Table II. Associations between changes in fat-free mass (FFM),
and variables showing lung function, body composition, systemic
inflammation, physical capacity, and dyspnoea at baseline.

D FFM
D FFM %
baseline

rho p rho p

Age (years) 0.06 0.76 0.09 0.66

Sex female –0.003 0.99 –0.03 0.89

FEV1 % of predicted 0.48 0.01 0.48 0.02

Pack years (years) 0.09 0.65 0.09 0.64

BMI (kg/m2) –0.18 0.37 –0.26 0.19

FFMI (kg/m2) –0.35 0.07 –0.44 0.03

CRP (mg/L) 0.18 0.39 0.19 0.38

Fibrinogen (mg/L) 0.47 0.03 0.49 0.02

12MWT (m) 0.08 0.68 0.07 0.75

Wpeak (watt) 0.20 0.30 0.16 0.42

Dyspnoea 0.48 0.02 0.44 0.03

0

1

2

3

4

5

C
o

u
n

t

–6 –5 –4 –3 –2 –1 0 1 2 3 4 5

D FFM (kg)

Median change 0.6 kg

Figure 2. Distribution of changes in fat-free mass (FFM) between
baseline and four months of training.

Table III. Associations between changes in fat-free mass (FFM),
and age, sex, lung function, dyspnoea, and fibrinogen. Estimates
(beta coefficients) are adjusted for all the variables in the table.

D FFM
D FFM of
baseline

R2 = 0.697 R2 = 0.682

Coeff. p Coeff. p

Age (years) –0.120 0.03 –0.24 0.07

Female sex –0.519 0.58 –0.658 0.77

FEV1 % of predicted 0.104 0.02 0.255 0.03

Dyspnoea CRDQ 0.336 0.01 0.661 0.03

Fibrinogen (mg/L) 0.588 0.16 1.63 0.11

Factors associated with change in fat-free mass in COPD 55



worsened dyspnoea (26). As dyspnoea has been
shown to be related to all subscores of St Georges
Respiratory Questionnaire, a low health-related qual-
ity of life is obvious in subjects with dyspnoea (27).
Dyspnoea can of course have many different explana-
tions, and some of them can probably be treated. In
malnourished patients with COPD nutritional inter-
ventions can improve quality of life (28). Strength
training results in less dyspnoea during exercise,
thereby making this strategy easier to tolerate than
aerobic training (29).
Our finding that age is correlated with difficulties to

increase FFM is consistent with the fact that cachexia
is more common in older age (30). CRP in our
patients with low and normal FFMI was within the
normal range, and there was no significant correlation
in the bivariate analysis between CRP at baseline and
change in FFMI after training. This is in accordance
with results of Eagan et al. who found, in a large
COPD population, that CRP was positively associ-
ated with FFMI (31), thus CRP was not elevated in
patients having lower FFMI. They concluded that
CRP is not elevated in cachectic COPD patients. Our
results and the results from Eagan et al. are in contrast
to a prominent theory suggesting that pathological
weight loss is at least partly explained by an increase in
systemic inflammation reflected in enhanced plasma
or serum concentrations of inflammatory markers
(32). A probable explanation for increased CRP in
COPD patients might instead be that active fat mass
tissue in obese patients is associated to higher sys-
temic levels of CRP (33).
There was a training response in our patients,

which was seen in both increased maximal capacity
(Wpeak) and 12-min walk distance (34-36), and there
was no significant difference in this response between
the low FFMI group and the normal FFMI group. We
found that FFM decreased slightly in the low FFMI
group and increased in the normal FFMI group, but
the difference between the two groups did not attain
statistical significance. In accordance with our results,
Berton et al. reported that both their depleted patients
(who were given nutritional supplementation and
endurance and strength training for 12 weeks) and
their non-depleted patients (who just got the 12 weeks
of training) slightly increased FFM and that there was
no statistically significant difference between the
groups (34). Two recent studies have shown improve-
ments in FFM in depleted patients as a result of
exercise training and nutritional supplementation,
whereas depleted control patients who just received
exercise decreased in FFM (36,37).
Our depleted patients received one oral nutritional

supplementation after training, i.e. twice a week,
whereas in the study by Berton et al. patients received

a daily polysaccharide supplementation if caloric
ingestion was judged inadequate (34). In the two
studies that improved FFM, one study gave essential
amino acid supplementation twice a day for 12 weeks
(37), and in the other study the patients were given
three oral liquid supplements per 24 hours for four
months (36). Thus, the amount and type of supple-
ment may be an important factor to consider. As
exercise capacity increases as a result of exercise
training independently of BMI (38), we suggest
that to improve FFM in depleted patients nutritional
supplementation has to be extensive.
While muscle mass can be readily increased by

progressive strength training, this would not be
expected from an aerobic training programme such
as ours. Strength training has been shown to have
greater potential to improve muscle mass and strength
than endurance training (39). In addition, it was
recently shown that cachectic patients can retain
the potential for skeletal muscle remodelling as a
result of strength training (40).
It was not possible to study the effectiveness of

supplementation during exercise training in patients
with low FFMI because of our small number of
patients. Another limitation is that potential con-
founding factors including physical activity and met-
abolic syndrome features were not measured. Our
training programme was not primarily aimed at
improving muscle mass but rather endurance capac-
ity. Another limitation is that we did not control for
daily caloric intake, i.e. patients might have dropped
in the normal dietary intake.
Our conclusion is that in COPD old age, low FEV1,

and high level of dyspnoea in daily life were, inde-
pendently of each other, related to less chance of
increasing fat-free mass by physical training.

Funding

This paper was supported by grants from the
Swedish Heart and Lung Association E011-02,
The Swedish Heart-Lung Foundation 2004-10-33,
and Bror Hjerpstedt’s foundation 2003-010.

Declaration of interest: The authors report no
conflicts of interest. The authors alone are responsible
for the content and writing of the paper.

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	Abstract
	Introduction
	Material and methods
	Exercise training
	Body composition
	Physical capacity
	Dyspnoea
	Systemic inflammation
	Lung function
	Statistics

	Results
	Discussion
	Funding
	Declaration of interest
	References