Peripheral Arterial Disease Clinical Trial
Official title:
The Effect of Different Forms of Exercise on Both the Clinical, Systemic and Local Biological Responses in Intermittent Claudication
Cardiovascular disease remain one of the leading causes of death in Australia, accounting
for 47637 (36%) of deaths in 2004.
Peripheral arterial disease (PAD) is a category of cardiovascular disease, characterised by
intermittent claudication. This is defined as walking induced pain, cramping, aching,
tiredness or heaviness in one or both legs that does not go away with continued walking and
is relieved with rest. It is estimated that between 5-10% of individuals aged over 50 years
suffer from claudication. The primary and most effective treatment for these patients is
focused on improving walking ability and functional status.
Current research has shown that approximately 30% of patients improve with exercise, while
30% continue to deteriorate and the rest show no change. The changes produced at a
biochemical and cellular level due to exercise are unknown. To help better understand this,
our study will assess the entire range of proteins expressed before and after exercise in
the skeletal muscle tissue of patients with intermittent claudication. This will help to
identifying key proteins that have a role in improving patient symptoms and outcome.
Why is this clinical problem important?
Peripheral Arterial Disease (PAD) is a major health problem in Australia, with a prevalence
of 15% in males aged over 65 years. The direct health care cost of PAD in Australia was
$180m in 1994, of which 78% was associated with hospitalisations. PAD is also a marker for
advanced cardiovascular disease (CVD) involving coronary, cerebral, renal and aortic
vessels; with a 2-3 fold increased risk of CVD-related mortality. In 2006-2007, 25,813
hospitalizations and 2,163 deaths were a result of PAD (Australian Institute of Health and
Welfare 2009). The ageing Australian population and the prevalence of PAD increases
(Australian Institute of Health and Welfare 2009), the national annual health expenditure on
cardiovascular disease is likely to increase, greatly exceeding the 5.4 billion dollars
spent in 2000-01 (Australian Bureau of Statistics 2006). The most frequent symptom of mild
to moderate PAD is intermittent claudication (IC), defined as walking-induced pain and
cramping in one or both legs (most often calves) that is relieved with rest. The primary and
most effective treatment for people with intermittent claudication is focused on improving
walking ability and functional status.
What is already known about the effect of exercise in intermittent claudication?
The beneficial effects of exercise training as a treatment have been confirmed in several
randomised controlled trials. The optimum form of exercise still hasn't been elucidated. The
mechanisms of improvement of claudication with exercise are largely unknown. Although
exercise stimulates an ischaemic-reperfusion (I-R) insult, repetitive exercise may produce
an adaptive response to this I-R insult. Other potential themes include effect of exercise
on stimulating or inhibiting angiogenesis and/or muscle protein synthesis.
Although the principal cause of IC is reduced blood flow to the lower limbs relative to
increased demand during exercise, the pathophysiology of IC is not completely understood.
For example, limb haemodynamics does not closely correlate with clinical presentation or the
limitations in peak exercise performance. Haemodynamic measures of the severity of PAD, such
as the ankle-brachial systolic blood pressure index (ABI) and blood flow by strain gauge
plethysmography, are poor predictors of exercise capacity in patients with IC.
Cross-sectional studies indicate that inflammation is associated with the presence,
progression and severity of PAD. This may explain the excess cardiovascular mortality, (at
least 50% at 10 years), seen in these patients. The effect of exercise on claudication has
been most studied with inflammatory markers in peripheral blood.
What is the importance of measuring protein expression in muscle tissue?
While peripheral blood bio-markers help in understanding the systemic manifestations of
claudication, it does not reflect what is happening in the muscles and microcirculation.
Most of the changes in protein expression are too subtle to be detected in peripheral blood.
The ease of acquisition does not correspond to ease of interrogation. The dynamic range of
proteins in serum makes analysis very challenging because high abundance proteins tend to
mask those of lower abundance; whilst a small number of proteins including albumin, Beta
2-macroglobulin, transferrin, and immunoglobulins may represent over 90% of serum
proteins11.
The protein complement of a cell or tissue is dynamic and reflects the age, life-cycle, and
conditions the cell is subjected to or a specific disease state. It is clear that in most
diseases, proteins are subjected to numerous changes including post-translational
modifications and/or proteolytic cleavage; equally in certain diseases, there is alteration
of protein expression. Messenger ribonucleic acid (mRNA) is the molecule encoding the
chemical blueprint for a protein. Yet the micro arrays examining differential expression of
mRNA will not provide information on post-translational modification, therefore the only way
to assess the impact of the proteins is at the protein level.
Some studies have investigated the difference in histochemical and biochemical
characteristics of skeletal muscle between patients with PAD and healthy age-matched
subjects. Most of the studies into muscle biopsy from patients with PAD have demonstrated
alterations in muscle fibre type distribution, denervation and alterations in muscle
metabolism with no insight into protein expression12, 13, 14. There is considerable evidence
that the metabolic status of skeletal muscle is perturbed in patients with PAD as compared
with age-matched healthy controls. Amongst the earliest observations was the unexpected
finding that the expression and activity of several mitochondrial enzymes are increased in
skeletal muscle from limbs with PAD. The skeletal muscles in patients with IC, do change
with exercise but the current evidence does not shed light on the mechanisms of change or if
the change is the same in all patients. We do already know that some patients improve with
exercise while others do not. A question thus arises as to whether there exists a
bio-diversity in these patients' response to exercise.
Armstrong et al studied disturbances in calcium homeostasis of skeletal muscle and suggested
that they might play a key role in the development of exercise-induced muscle damage. Some
of the immediate muscle changes after exercise have been attributed to protein degradation
is initiated by non-lysosomal cysteine proteases, such as calpain. The elevation in
intracellular calcium post-exercise can activate the calpains. Muscle tissue expresses three
distinct calpains, including the well-characterized ubiquitous calpains - m- calpain,
μ-calpain and n-calpain. Wang et al have concluded, in animal studies, that the increased
levels of the protease m-calpain, promotes muscle injury whereas the calpastatin protein
expression might execute a protective function for muscle injury. This has not yet been
investigated in human studies. It can be hypothesised that the levels of calpastatin and
m-calpain are important in explaining the variable response to exercise in IC and why some
patients improve and others do not.
There is some conflicting evidence on the benefit of exercise. Tsai et al have found that
the normal training effect on the glucose transporter 4 (GLUT4) gene expression was
completely eliminated by both acute and chronic ischemia at the pre-translational level. In
addition, the chronic ischemia-induced muscle atrophy was seen to be more severe in the
exercise-trained rats than in the untrained rats. This result suggests that for individuals
with impaired microvascular conditions, exercise training might not be beneficial in
maintaining muscle mass. Thus the effect of exercise training in human subjects with IC
(ischaemia) is yet to be elucidated.
We know that all subjects differ in their capacity for exercise and patients with
intermittent claudication are no different. Patients undergoing exercise for intermittent
claudication, would be different in terms of their expression of proteins due to exercise.
For this reason, patients would act as their own controls by means of a biopsy from an
unaffected muscle of each individual.
An open ended mass spectroscopy examination of proteins in the exercising skeletal muscle
would give an insight into the mechanistic pathway of the exercise effect in intermittent
claudication.
What is the relation between protein expression and inflammation in the exercise with
intermittent claudication?
The clinical model of exercise inducing an ischaemia-reperfusion type injury has been
substantiated by evidence of markers of inflammation. Neutrophils are the first cells to
begin accumulating in the tissue at the injury site, destroying necrotic tissue through
phagocytosis while working in conjunction with resident macrophages from the muscle tissue
itself. Neutrophil presence has been documented in muscle after various types of eccentric
exercise. A study looking at neutrophil function in exercising claudicants showed increased
neutrophil activation manifest by increased expression of the neutrophil adhesion receptor
cluster of differentiation antigen IIb (CD11b) and degranulation manifest by an increase in
plasma neutrophil elastase. This occurred immediately after exercise in these patients with
intermittent claudication. Whether this equates to a trend to predict outcomes is still not
clear.
The protease m-Calpain is chemotactic factor for neutrophils and may play a role in the
local and systemic inflammatory response. Such adaptations in cellular inflammatory
responses have been reported earlier by Kunimatsu et al. Together with Calpastatin, these
proteins may hold a key in the link between local muscle damage, repair and inducing a
systemic inflammatory response.
Chemical modification of proteins may play a role in the pathogenesis of disorders ranging
from diabetes to atherosclerosis and ischemia-reperfusion injury and perhaps to the aging
process itself. Advanced Glycosylation End products (AGEs) are the end products of
glycosylation reactions in which a sugar molecule bonds to either a protein or lipid
molecule without an enzyme to control the reaction. The formation and accumulation of AGEs
has been implicated in the progression of age related disease, in particular cardiovascular
disease. They have a range of pathological effects, including inhibition of vascular
dilatation by interfering with nitric oxide (Endothelium Derived Relaxation factor), binding
macrophage and endothelial cells to induce the secretion of inflammatory cytokines and
enhancing oxidative stress. We hypothesise that exercise stimulates glucose uptake by the
endothelial cells increasing the synthesis of AGE's. It remains to be determined whether
exercise again enhances or reduces this process.
The aim of this study is to examine inflammatory biomarkers, including Interleukin-6 (IL-6),
Neutrophil elastase and Advanced Glycated End-products with proteins known to influence
tissue damage or repair (Calpains and Calpastatin) to determine the effect of different
forms of exercise on this process, in order to determine
1. Is exercise appropriate for all patients? i.e.
1. Do all patients respond with a pro inflammatory response? and
2. Does exercise produce an adaptive response to this in all patients? or
3. Does exercise stimulate an I-R insult in some patients that is not reduced by
exercise training?
4. What is the local tissue response to exercise in terms of tissue damage or repair
(as measured by protein analysis)
2. What is the best form of exercise for these suitable patients?
3. Is there a biodiversity in patients' response to exercise in terms of
1. Systemic inflammatory response (based on IL-6, Neutrophil Elastase & AGE's)?
2. Local response (based on protein analysis)?
4. Does the physiological response to exercise in these patients reduce the risk of CVD
related morbidity/mortality?
a. As evidenced by changes in cardiopulmonary exercise testing (CPET) outcome
parameters and endothelial function.
5. Is impaired endothelial function reversible? a. As measured by flow-mediated
dilatation.
The combined use of data from systemic blood and local muscle tissue would help to
characterise the metabolic and functional consequences of age associated PAD changes in
skeletal muscle. It would also help to identify a mechanistic pathway by which exercise
exerts its effect on the patient with intermittent claudication.
;
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