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36 SA JOURNAL OF PHYSIOTHERAPY 2008 VOL 64 NO 2

Exercise Overcomes
Muscle Weakness Following on
Trauma and Critical Illness

Scholar ly

Ar t ic le

INTRODUCTION
South Africa has a high incidence of 
violence and death due to high levels of
interpersonal violence and motor vehicle
accidents. Norman and colleagues (2007)
reported a homicide rate in South Africa
that was seven to nine times greater than
global reported rates. The authors also
reported a mortality rate related to road
traffic accidents in South Africa of 
double the global rate. Thomson (2003)
stated that trauma kills young people in
the prime of their economically produc-
tive lives. Trauma is often referred to as
the ‘hidden epidemic’ as it gets much
less media attention than the human
immunodeficiency virus/acquired immu -
nodeficiency syndrome (HIV/AIDS)
pandemic but has an equally high mor-
tality rate (Thomson 2003). Survivors of
trauma often present with serious
injuries and illness that necessitate

admission to the intensive care unit
(ICU). Severity of illness determines the
length of ICU and hospital stay. The
2002 Brussels Roundtable Discussions
among intensive care practitioners con-
cluded that survivors of intensive care
suffered from poor functional capabi -
lities, decreased quality of life (QOL),
and decreased rate of return to work and
placed an increased burden and stress on
families and informal caregivers. These
factors led to increased economic costs
for the patient, families and the society
(Angus & Carlet 2003).
The effects of immobility and critical

illness on the human body (short and
long-term) are not always well-under-
stood. The aims of this review article 
are to a) provide information to physio-
therapists on the human body’s response
to trauma; b) explain the pathogenesis of
muscle weakness due to inflammation
and the resulting impairments that sur-
vivors present with and c) identify the
role of exercise prescription in counter-
acting these impairments both during
and after hospital stay.

TRAUMA AND THE HUMAN BODY
Figure 1 outlines the responses of body
systems to trauma. Local and systemic
responses are activated by various fac-
tors such as injury, surgery, burns, dehy-
dration, sepsis and acute medical illness.

Correspondence to:
Heleen van Aswegen
Physiotherapy Department,
School of Therapeutic Sciences,
University of the Witwatersrand,
7 York Road, Parktown
Johannesburg 2050
Tel: (011) 717-7302 (w)
Fax: (011) 717-3719 (w)
Email: helena.vanaswegen@wits.ac.za

ABSTRACT:  Injuries related to trauma are often seen in South African
intensive care units. Systemic inflammation and the development of sepsis
lead to prolonged intensive care unit and hospital stay. The effects of 
critical illness and immobility on the human body are not always well-
understood. This review article explains the pathogenesis of muscle weak-
ness due to inflammation and identifies the role of exercise prescription in
counteracting impairments that may be identified in survivors of trauma
during and after hospital stay.

KEYWORDS: TRAUMA, INFLAMMATION, MUSCLE WEAKNESS, EXERCISE.   

Acute injury/trauma leads to loss of lean
body and skeletal mass and precedes the
process of recovery and wound repair.
Inflammation, as a result of injury, 
consists of humoral [triggering of coag-
ulation and fibrinolytic cascades as well
as kinin (blood protein that acts as
vasodilator during inflammation i.e.
bradykinin)] and cellular (activation 
of leukocytes and endothelial cells)
responses. Exacerbation of the inflam-
matory response can lead to the develop -
ment of a systemic inflammatory
response syndrome (SIRS) due to an
imbalance in the production of pro-
inflammatory cytokines (Hietbrink et al
2006). Anti-inflammatory cytokines are
released to restore this imbalance but
over activation leads to either a compen-
satory anti-inflammatory response or a
mixed antagonist response (Hietbrink et
al 2006; Osuchowski et al 2006). The
patient’s immune system is in disarray
and the patient becomes very suscep -
tible to infection which might result in
septic syndrome and ultimately multiple
organ dysfunction (MOD) (Hietbrink et
al 2006; Osuchowski et al 2006).
The initial response to trauma is 

to access energy from endogenous fat
oxidation. Fat provides most of the
body’s energy requirements during the
period in which no food is ingested. Fat
is mobilized from fat stores and converted

Van Aswegen H, PhD1;
Myezwa H,

MSc Physiotherapy1

1
Physiotherapy Department,
School of Therapeutic Sciences,
University of the Witwatersrand.



SA JOURNAL OF PHYSIOTHERAPY 2008 VOL 64 NO 2          37

to free fatty acids and glycerol. These
are then circulated to tissues such as the
large muscles which can burn the fatty
acids directly. Blood sugar starts to rise
slowly and insulin production from the
pancreas is inhibited (Boffard 2003;
Winkler & Manchester 1996). A meta-
analysis of randomised controlled trials
(RCT) on insulin therapy administration
during critical illness showed that
hyperglycemia is common in patients
with critical illness and also may play a
role in the activation of the tissue factor
pathway of coagulation (Pittas, Siegel 
& Lau 2004). This may lead to the
development of acute thrombosis. The
authors concluded that insulin therapy
and tight glucose control had a benefi-
cial effect on short-term morbidity and
mortality (Pittas, Siegel & Lau 2004).
Hyperglycaemia may contribute to the

important stimulant of aldosterone. 
This occurs via the renin-angiotensin
system and adrenocorticotropic hor-
mone (ACTH) both of which stimulate
the adrenal cortex to produce aldos-
terone. Aldosterone supports circulation
through decreased excretion of sodium
bicarbonate through the kidneys. Blood
loss also stimulates the production of
vasopressin/antidiuretic hormone (ADH)
from the posterior pituitary, with conse-
quent fluid retention and vasoconstriction
of the large blood vessels. Increased 
catecholamine secretion is the main
endocrine response to trauma. These
catecholamines, especially epinephrine,
inhibit insulin production and increase
insulin resistance. This causes an initial,
slight elevation of the blood sugar and a
gradual rise in glucagon levels (Boffard
2003; Davis 2001).

patient’s mortality rate. Gale and co-
workers recently published results from
a retrospective study that was performed
on all trauma patients in their urban 
hospital (Gale et al 2007). They found
that poor glycaemic control was asso -
ciated with increased morbidity and
mortality in critically ill trauma patients
and was more pronounced in non-dia-
betic patients. They also found a greater
prevalence of urinary tract infections
and complications in non-diabetic trauma
patients with poor glycaemic control.
These results have prompted many
South African trauma surgeons to treat
their patients, regardless of admission
diagnosis, with insulin therapy to main-
tain glucose levels within the normal
range during their ICU stay. 
Trauma also disrupts endocrine

homeostasis. Blood loss is the most

Figure 1: Schematic representation of the response to trauma



38 SA JOURNAL OF PHYSIOTHERAPY 2008 VOL 64 NO 2

Trauma patients often develop circu-
latory shock due to severe blood loss,
myocardial contusion, cardiac tam -
ponade, tension pneumothorax or spinal
injury. Shock leads to the development
of various degrees of cellular damage,
depletion of cellular energy stores
(ATP), myocardial dysfunction, oliguria
(decrease in urine output) and splanchnic
ischaemia due to hypoperfusion. Hyper -
ventilation occurs due to lactic acidosis
and reduced pulmonary blood flow that
leads to ventilation-perfusion mismatch
and shunting (Schiller & Anderson
2001; Tatsumi et al 2000). SIRS results
in capillary leak associated with the
development of the acute respiratory
distress syndrome (ARDS) manifested
by progressive posterior atelectasis.
Respiratory muscle fatigue from muscle
hypoperfusion and increased energy
expenditure may lead to respiratory 
failure (Schiller & Anderson 2001;
Skowronski 1998). The patient’s prog-
nosis depends on the severity of the
injury, age and pre-existing illnesses.
Survival depends on maintenance of
oxygen delivery and effective surgical
intervention (Schiller & Anderson 2001;
Skowronski 1998).  

THE INFLAMMATORY PROCESS
The human body is protected from a
wide range of micro-organisms through
the immune system mediated through
antigen presenting cells and inflam -
matory cells. These cells produce pro-
inflammatory and anti-inflammatory
cytokines, lymphokines and eicosanoids
that mediate the response to an inflam-
matory stimulus (infective or not). 
Pro-inflammatory mediators include
interleukins (IL) 1 and 6, tumour necrosis
factor-alpha (TNF-a), prostaglandins,
leukotrienes and reactive oxygen
species (ROS) (Grimble 1999; Mukho -
padhyay, Hoidal & Mukherjee 2006).
Anti-inflammatory mediators cause
immunosuppression and include IL-4,
IL-10, IL-13, soluble TNF receptors and
IL-1 receptor antagonist. Cytokines such
as the IL and TNF-a are released into the
circulation by macrophages and mono-
cytes in inflamed tissues. Cytokines are
proteins that are produced by white
blood cells. IL facilitates inflammation
and promotes white cell proliferation

and infiltration. IL can be classified as
pro-inflammatory, anti-inflammatory or
have both properties (Winkelman 2004).
Research is frequently conducted on the
role of IL-1, IL-6 and IL-10 in critical
illness (Winkelman 2004). 

Interleukin-1
IL-1 can be categorised as IL-1A and 
IL-1B. Both bind to receptors on the cell
membrane (Winkelman 2004) and small
amounts can elicit an inflammatory
response throughout the body. IL-1 is
therefore associated with the develop-
ment of SIRS and causes clinical reac-
tions such as fever, malaise and loss of
appetite and sleep (Winkelman 2004).
IL-1 promotes the adhesion of leuko-
cytes to the endothelium resulting in
capillary leak, stimulates the production
of white blood cells from bone marrow
and promotes prostaglandin production.
Both IL-1A and IL-1B are toxic to 
muscle tissue (Winkelman 2004). IL-1A
influences insulin-growth factor and 
this leads to muscle protein breakdown.
IL-1B is known to be involved with
apoptosis (planned cell death with sub-
sequent phagocytosis by other cells) and
contributes to the reduction of muscle
mass (Winkelman 2004).

Interleukin-6
IL-6 is released from T-cells, mast cells,
epithelial cells, pulmonary epithelial
cells and myocytes. It stimulates the
activation of neutrophils and natural
killer cells with further release of IL-1
and TNF-α. It enhances B-cell produc-
tion as well as antibody production by
B-cells (Winkelman 2004) and as
inflammation becomes chronic it slows
the production of IL-1 and TNF-α and
promotes the release of anti-inflamma-
tory mediators. Research has shown that
persistently high levels of circulating
IL-6 are associated with an increased
risk of mortality in patients suffering
from sepsis, trauma or burns (Winkelman
2004). IL-6 enhances the infiltration of
myocytes with prostaglandins, which leads
to breakdown of protein, dege neration
of myocytes and muscle atrophy. IL-6
has been associated with maintenance of
homeostasis during exercise through the
regulation of glucose meta bolism by
skeletal muscles (Winkelman 2004).

Interleukin-10
IL-10 is an anti-inflammatory cytokine
that inhibits the production of pro-
inflammatory cytokines by macrophages
or monocytes. Low levels of IL-10 in
the ICU patient can be associated with
excessive inflammation and muscle
damage and lead to the development of
SIRS. High levels of IL-10 may provide
protection against inflammatory myo -
pathy. Myocyte damage as a result of
disease progression is best controlled by
maintaining a balance between pro-
inflammatory cytokines (IL-1 and IL-6)
and anti-inflammatory cytokines (IL-10)
(Pretorius 2003; Winkelman 2004).

Tumour Necrosis Factor-Alpha
TNF-α is released into the circulation
during the early phase of injury or infec-
tion. TNF-α produces similar metabolic
and physiologic actions to IL-1
(Grimble 1999; Mukhopadhyay, Hoidal
& Mukherjee 2006). 

Reactive Oxidant Mediated Injury
Recent developments in the medical 
literature propose that systemic oxida-
tive stress plays a role in the develop-
ment and manifestation of critical illness.
Oxidative stress has been defined as “a
condition in which accumulation of free
radicals or the inability of antioxidants
to counter the accumulation of free 
radicals creates an imbalance between
production of ROS and protection of
antioxidants” (Goodyear-Bruch & Pierce
2002, pp 545). In health small amounts
of ROS are essential to life, forming a
major component of our intrinsic defence
systems in the form of phagocyte
derived hydrogen peroxide and hypo -
chlorous acid. These and others that are
produced as by-products of normal
metabolism, (such as purine and arachi-
donic acid metabolism) are neutralized
by the major endogenous anti-oxidants
glutathione, catalase, superoxide dis -
mutase and albumin and exogenous anti-
oxidants such as vitamin C, vitamin E,
β carotene and selenium. However in 
illness, increased generation of ROS
results in the consumption of anti-
 oxidants and an oxidant/anti-oxidant
imbalance ensues (Cuzzocrea, Thie-
mer man & Salvemini 2004; Salvemini
& Cuzzocrea 2002). ROS themselves 



SA JOURNAL OF PHYSIOTHERAPY 2008 VOL 64 NO 2          39

stimulate the inflammatory response by
increasing the release of cytokines and
thus activate the inflammatory cascades
(Goodyear-Bruch & Pierce 2002). Loss
of control of the production of ROS in
SIRS and sepsis leads to direct cellular
injury through oxidative damage to cel-
lular proteins, interstitial cell structures
and the destruction of cell membranes.
This sequence of events may result in
multiple organ failure (Abilés et al 2006;
Goodyear-Bruch & Pierce 2002; Zhang,
Slutsky & Vincent 2000). Ely and col-
leagues stated that MOD syndrome
occurring as a result of sepsis is the most
common cause of mortality among criti-
cally ill patients without coronary compli -
cations (Ely, Kleinpell & Goyette 2003).

Pathogenesis of Muscle Weakness
TNF-a increases the production of cata-
bolic cytokines (IL-1 and IL-6) and causes
anorexia (Jackman & Kandarian 2004;
Reid & Li 2001; Winkelman 2004). This
catabolic effect leads to the disruption of
myogenesis (formation of muscle tissue)
(Andreoli et al 1993). It causes muscle
breakdown in inflammatory diseases
such as cancer, chronic obstructive 
pulmonary disease (COPD), AIDS and
sepsis, which contributes to weakness,
fatigue and limited mobility (Reid & 
Li 2001). TNF-α binds to Type 1 TNF-α
receptors leading to an increased pro-
duction of ROS from mitochondrial
electron transport chains in skeletal
muscle (Reid & Li 2001). Nuclear 
factor-κB is activated causing increased
activity of the ubiquitin/proteasome
pathway that accelerates degradation of
the bulk of all intracellular proteins,
especially myofibrillary protein and 
promotes muscle weakness (Jackman &
Kandarian 2004; Reid & Li 2001;
Winkelman 2004). Reid compared the
effect of TNF-α on the contractile 
function of a murine diaphragm and the
flexor digitorum brevis muscle. They
found that TNF-α induced contractile
dysfunction on both muscles through its
effect on the myofilaments. They stated
that TNF-α promotes the production of
ROS and nitric oxide derivatives (Reid,
Lännergren & Westerblad 2002). 
Jackman and Kandarian postulated

that TNF-a and other cytokines act as
triggers for muscle wasting due to the

effect of cachexia on the body as a
whole. They stated that ROS contribute
to the cytokine-induced muscle wasting
(Jackman & Kandarian 2004). Lanone
and colleagues (2000) investigated the
effects of sepsis on muscle contractile
failure in a group of 16 patients.
Biopsies from the rectus abdominis
muscles were compared with biopsies
taken from patients without sepsis that
underwent elective surgery. The authors
found a marked decrease in the con -
tractile force of the rectus abdominis
muscles of patients with sepsis compared
to the controls. They ascribed this 
finding to the fact that high levels of
nitric oxide synthase were present in the
muscle samples taken from patients with
sepsis. Nitric oxide synthase leads to the
production of nitric oxide which inter-
acts with ROS to form peroxynitrites
that directly attack contractile proteins
(Lanone et al 2000). Eikermann and 
colleagues (2006) performed a similar
experiment on patients that had survived
sepsis and MOD syndrome. They inves-
tigated the effect of sepsis and MOD
syndrome on the strength and fatigue of
the adductor pollicis (AP) muscle. 
They found that AP muscle force was
significantly decreased (by 30%) com-
pared with controls but that no fatiga -
bility was observed. They concluded that
the decrease in muscle force was due 
to a sepsis-induced myopathy as the
compound muscle action potential and
nerve conduction velocity was normal,
implying no neural injury (Eikermann et
al 2006).

Prolonged immobilisation and its effect
on the human body
The physical deconditioning that result
from prolonged bed rest is not new to
medical science. Hippocrates described
loss of muscle strength and reduced exer-
cise performance following prolonged
bed rest and inactivity in the earliest
medical journals. Bed rest is generally
an unavoidable consequence of critical
illness (Convertino, Bloomfield &
Green leaf 1997; Winkelman 2004). The
adverse effects of prolonged bed rest in
the supine position include loss of
hydrostatic pressure in the cardiovas -
cular system below the level of the
heart; elimination of longitudinal com-

pressive forces on the lower limbs and
spine with reduced muscle force exerted
on all weight bearing bones; a signifi-
cant decrease in total energy utilization
and detrimental effects on the muscu-
loskeletal system with regard to muscle
power, endurance and size of muscle
fibres (Convertino, Bloomfield & Green-
leaf 1997). This results in weakness and
easy fatigability of the diaphragm and
skeletal muscles (Winkelman 2004).
Disuse atrophy is exacerbated by the
effects of steroids and neuromuscular
blocking agents on the muscle fibres
(Bolton 1996), malnutrition and the
inflammatory response and prolonged
periods of continuous mandatory venti-
lation (Winkelman 2004). 

The Effect of Exercise on Serum Levels
of Pro- And Anti-Inflammatory Cytokines
IL-6 generally increases within the 
muscle in response to exercise. The IL-6
cytokine has a complex action and has
been referred to as ‘good guy or bad
guy’ (Pederson et al 2007). An important
finding in healthy subjects regarding 
IL-6 is that during exercise its function
changes from pro-inflammatory to anti-
inflammatory. IL-6 inhibits TNF alpha
production and enhances insulin uptake
(Pederson et al 2007).
Winkelman suggests that exercise

can influence the serum levels of 
pro- and anti-inflammatory cytokines by
restoring the imbalance that exists 
during critical illness and suggests that
exhaustive exercise has the potential to
increase the levels of IL-6, IL-10 and
TNF-α dramatically (Winkelman 2004).
Similar effects of exhaustive exercise on
the release of ROS were reported by
Kalokerinos (2005). Moderate exercise
slows the atrophic changes that occur
due to disuse by improving blood flow
to muscles and joints. Therapeutic acti -
vities that are performed by physio -
therapists and nursing staff on patients
in the ICU include positional changes
from supine to side lying, passive joint
range of motion (ROM) movements, 
sitting up over the side of the bed and
transferring from bed to chair. Winkelman
and colleagues studied the effect of 
low-level activity (position changes and
passive ROM movements) on the levels
of IL-6 and IL-10 in a group of 10



40 SA JOURNAL OF PHYSIOTHERAPY 2008 VOL 64 NO 2

patients with prolonged MV. They
reported that activity did not exacerbate
the levels of circulating IL-6 and IL-10
and that low-level activity in the ICU
may play a role in restoring the balance
in cytokine activity. The small sample
size however restricted the interpreta-
tion of their findings (Winkelman et al
2007). There exists no clinical research
data regarding the appropriate intensity,
frequency or mode of exercise in the
acutely ill patient. Stiller and Phillips
(2003) suggest that exercise intensity,
frequency and mode be adjusted to each
individual patients’ medical condition
and level of debilitation. These authors
recommend starting with low level
activities (bed exercises and lifting of
the patient into a chair) that are gradually
progressed to basic mobility (standing
and walking) (Stiller & Phillips 2003). 

In summary, inflammation inhibits
the production of protein and the protein
content of muscle tissue. This leads to
loss of muscle mass and power.
Inactivity, in the presence of inflamma-
tion, may contribute to the destruction of
muscle cells. IL-1, IL-6 and TNF-α are
involved in muscle breakdown during
an inflammatory reaction whereas IL-10
inhibits the actions of the above-
mentioned cytokines.  Low-level exer-
cise may slow the atrophic changes that
occur due to disuse by improving blood
flow to muscles and joints provided the
patient is not too sedated to participate
in these exercises.

Exercise and its potential role inreha -
bilitation
It is well known that physical fitness
plays a key role in a person’s ability to
perform activities of daily living (ADL).
Physical fitness also influences their
ability to participate in sport and exer-
cise and aids in improving QOL (Blair,
LaMonte & Nichaman 2004), through the
known effects on the musculoskeletal,
respiratory and cardiovascular systems
(Warburton, Nicol & Bredin 2006). As
discussed above, prolonged bed rest
results in muscle weakness, poor muscle
endurance and rapid loss of calcium
from bone (Conroy & Earle 2000;
Convertino, Bloomfield & Greenleaf
1997). Other beneficial effects of exer-
cise are increased muscle mass and

strength due to a) improved neural con-
trol, b) increased muscle cross-sectional
area, c) new bone formation stimulated
through weight-bearing exercises, 
d) increased synthesis of high-density
lipoproteins and improved insulin sen -
sitivity (Taylor, Bell & Lough 2002).
Muscles develop new capillaries which
increase the oxygen extraction ratio.
More skeletal muscle cell mitochondria
are produced as a result of aerobic exer-
cise and maximal oxygen uptake
improves as physical fitness improves
(Williams 2000). As maximal oxygen
uptake increases, less energy is utilized
to perform ADL and health-related QOL
improves. 
Rehabilitation programmes that con-

sist of aerobic and resistance exercises
are commonly used in the chronic 
cardiac and pulmonary disease popula-
tions with encouraging results (AACVPR
2004). Jones and co-workers (2003) are
the only researchers to date to test the
effectiveness of a rehabilitation pro-
gramme on the recovery of survivors of
critical illness in a RCT. They compiled
a 93-page rehabilitation package that
consisted of a self-directed exercise pro-
gramme, diagrams and illustrations. The
manual also contained advice on a wide
range of psychological, psychosocial and
physical problems that the ICU survivor
could expect to encounter after they had
recovered from critical illness. Subjects
(n = 69) and controls (n = 57) were 
contacted telephonically three times per
week after discharge to monitor progress
however subjects in the experimental
group were also encouraged to use the
self-help rehabilitation manual. All sub-
jects were tested at follow-up clinics at
eight weeks and six months. The authors
found that the SF-36 physical function
score for subjects in the experimental
group was closer to normal and signi -
ficantly different from those in the con-
trol group (Jones et al 2003). 
There are few studies that investigated

the effects of critical illness on recovery
of exercise capacity in survivors over
the first six months to one year after 
discharge. Herridge and colleagues
(2003) evaluated the outcome of 109
adult survivors of ARDS over a one-
year period following discharge. These
patients had a median injury severity

score (APACHE II) of 23, median ICU
length of stay (LOS) of 25 days and a
median hospital LOS of 48 days. They
found that survivors of ARDS still had
limitations in functional abilities one
year following discharge. They ascribed
this to the severity of muscle wasting
that took place in hospital and the 
resultant weakness that persisted after
discharge. They emphasized that extra-
pulmonary disease was the main cause
of limitations in exercise capacity in
these subjects (Herridge et al 2003). Hui
and colleagues (2005) examined the
impact of severe acute respiratory syn-
drome (SARS) on the recovery of 
110 survivors at three and six months
following discharge from ICU. A mean
hospital LOS of 32.4 days was reported.
The authors reported that survivors of
SARS had significantly lower levels of
functional ability and health status when
compared to the normal population at
six months. They ascribed these findings
to muscle deconditioning and steroid-
induced myopathy (Hui et al 2005). 
Due to the deconditioning that

patients present with after prolonged
bed rest, the only form of aerobic 
exercise they perform comfortably and
conveniently is walking (Warburton,
Nicol & Bredin 2006).  Walking involves
the large muscle groups and has few, 
if any, side effects and has potential 
benefits of aerobic exercise (Morris &
Hardman 1997). Stiller and Phillips
(2003) suggests 50 - 60% of maximal
HR as a baseline level of intensity for
increasing patient fitness after dis-
charge. The introduction of resistance
and flexibility exercises for survivors of
critical illness for upper and lower limb
as well as trunk muscles should be done
gradually in order to allow for wound
healing to take place. 

CONCLUSION
There is a dearth of literature on the
recovery of muscle strength and exer-
cise capacity in survivors of critical 
illness over the first 12 months after 
discharge from the hospital. Physio -
therapists need to be aware of the patho-
genesis of muscle weakness during 
critical illness and how their inter -
ventions (exercise) influence patient
outcome in and after ICU. 



SA JOURNAL OF PHYSIOTHERAPY 2008 VOL 64 NO 2          41

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