Low-Intensity Exercise
Delays Onset Of Congestive Heart Failure, Markedly Extends Lives Of Rat
Model Closely Reflecting Human Disease
Many
associated physiological changes also suppressed, but mechanisms aren’t
known; level of exercise is critical
BETHESDA, Md. (Nov. 30, 2005) – A classic clinical
dilemma faces doctors treating patients with congestive heart failure (CHF):
while exercise generally protects the normal heart from cardiovascular
disease, will exercise potentially “improve the prognosis of patents with
CHF, or (will it place) a further excessive demand on an already
over-stressed myocardium”?
That’s how a new research paper poses the question, and
its positive but still tentative results show: “Briefly we found that low
intensity exercise training markedly delayed the onset of overt CHF without
a reduction in antecedent hypertension. Additionally, we found that some,
but not all, of the classic cellular and systemic physiological alterations
normally associated with the development of overt CHF were attenuated with
exercise training.”
It’s not an idle issue. The American Heart
Association (AHA) 2005 Statistics Update reports that 65 million
Americans have high blood pressure (hypertension) and nearly 5 million are
suffering from CHF, where the chances of survival drop rapidly, as about 75%
of patients die within 8 years after diagnosis.
“The key findings in this study,” according to
laboratory director Russell L. Moore, “are that (1) exercise can delay the
onset of decompensated heart failure and improve survivability and (2) this
effect is strongly dependent on the level of intensity of the exercise. You
can push the level over the edge quickly,” he added. “Not that long ago,
clinicians were afraid to even suggest a little exercise in patients with
CHF. However, our study, along with several human studies, shows a definite
trend indicating that moderate intensity exercise has a potential role in
stemming the downward spiral in heart failure,” Moore said.
The paper, “Low-intensity exercise training delays the
onset of decompensated heart failure in the spontaneously hypertensive heart
failure (SHHF) rat,” appears in the November edition of the American
Journal of Physiology-Heart and Circulatory Physiology, published by the
American Physiological Society. Research was Craig A. Emter, Sylvia
A. McCune, Genevieve C. Sparagna, and Russell L. Moore at the University of
Colorado at Boulder, and M. Judith Radin at Ohio State University.
Exercise could delay use of drug interventions,
improve quality of life
Moore noted that the experiment was performed “on an
animal model of CHF that shares many striking similarities to human CHF and
we found that low-intensity exercise works in a way that is consistent with
preliminary human results. Using exercise early in the disease might leave
more expensive options like drug therapies until later, thus avoiding their
inevitable side-effects. At the same time, it’s likely that even low-level
exercise has the additional potential of an improved life style.”
Moore said the human equivalent of the exercise in the
experiments would be a “brisk, but not taxing, walk.” The paper noted that
“our results underscore the importance of using low intensity exercise at a
‘tolerable intensity’….(The) final training intensity was quite low as
evidenced by the absence of a training-induced increase in skeletal muscle
citrate synthase activity or body weight loss.”
Model studies show decisive protection due to
exercise, danger of over-exertion
The experiment involved three sedentary control groups
(9 months, 15 months and 22 months of age) and two groups of rats that
“trained” for six months; one group starting training at 9 months of age,
the other at 16 months of age. The subjects were spontaneously hypertensive
heart failure (SHHF) rats. True lean male SHHF rats develop hypertension at
3-4 months and spontaneously develop terminal overt CHF at 18-23 months,
100% of the time. The onset of hypertension preceding CHF in this model is
particularly important because 75% of human CHF cases have antecedent
hypertension, the 2005 AHA Update reports.
The exercise training started at 9 and 16 months of
age, consisting of treadmill running three days a week, 45 minutes a day for
six months. During the first month of training, the speed was increased from
10 meters/minute to 17.5 m/min. However three rats in the 9-month group
experienced sudden death, though no animals in the 16-month group were
adversely affected by the higher speed. Following the deaths of the younger
rats, the speed was reduced to 14 m/min, and no further deaths occurred.
After six months of training, when the two oldest
groups were 22 months of age, nine rats in the oldest sedentary group were
near death in severe, end-stage decompensated heart failure (one had already
died) and the experiment was terminated to allow for improved tissue
analysis and comparison. Exercise improved survivability (p < 0.01) since
all (nine) rats that started training at 16 months of age were still alive.
Exercise delays or suppresses many physiological
changes associated with CHF
In addition to the delayed onset of CHF and increased
mortality, the exercise regimen “prevented or suppressed alterations in
myosin heavy chain isoform expression, cardiac cell morphology, proteinuria,
plasma ANP, and body composition that normally occur with the development of
overt heart failure,” the paper reported. “Furthermore, the model of
exercise training and heart failure described in this work may ultimately be
of value in dissecting out the specific cellular and molecular processes
that are influenced by training and that are required for improved survival
in a setting of developing heart failure,” the paper concluded.
Next steps
Moore said the experimental results “are only the
beginning” in trying to understand “how the heart interprets the exercise
stimulus and what mechanisms are responsible for protecting the heart from
going into heart failure.” Moore outlined the following areas of interest:
-
Determining mitochondrial function and preservation of
aerobic energy metabolism, which is one theory behind the downward spiral
to heart failure.
-
When does heart failure start, at what point can exercise
have the most effect and at what point does exercise become non- or
counter-productive in CHF?
-
The current study involved males, but what are the effects
of low-intensity exercise on females?
-
What could the impact on longevity be of different exercise
regimens? The current study was stopped somewhat arbitrarily to allow good
comparative tissue analysis when all the sedentary rats were dead or near
death. Studying the long-term effects of exercise potentially could lead
to other avenues of inquiry.
Source and funding
The paper, “Low-intensity exercise training delays the
onset of decompensated heart failure in the spontaneously hypertensive heart
failure (SHHF) rat,” appears in the November edition of the American
Journal of Physiology-Heart and Circulatory Physiology, published by the
American Physiological Society. Research was Craig A. Emter, Sylvia
A. McCune, Genevieve C. Sparagna, and Russell L. Moore at the Department of
Integrative Physiology, University of Colorado at Boulder, and M. Judith
Radin at the Department of Veterinary Biosciences, Ohio State University,
Columbus.
Research was supported by NIH/National
Heart, Lung, and Blood Institute (Moore) and American Heart Association
Pacific Mountain Affiliate (Sparagna and McCune).
Editor’s note: The media may obtain a copy of
Emter et al. by contacting Donna Krupa, American Physiological Society,
(301) 634-7209, cell (703) 967-2751 or
dkrupa@the-aps.org.
* * *
The
American Physiological Society was founded in 1887 to foster basic and
applied bioscience. The Bethesda, Maryland-based society has more than
10,000 members and publishes 14 peer-reviewed journals containing almost
4,000 articles annually.
APS
provides a wide range of research, educational and career support and
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mechanisms of diseased and healthy states. In May 2004, APS received
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