Contact:
Christine Guilfoy
Office: (301) 634-7253
cguilfoy@the-aps.org
Periodic ‘Deep Inflation’ Helps Prevent
Ventilator-Induced Lung Injury
BETHESDA, MD. (July 25, 2006) – Ventilation therapy
burst into the public consciousness more than 60 years ago with the “iron
lung” and the polio epidemic. Mechanical ventilation has come a long way
since then and is used today with patients who cannot breathe on their own
because of trauma, lung injuries and chronic lung disease.
But ventilation demands a delicate balance between over
inflating and under inflating the lungs, either of which can lead to further
injury. Researchers have found that pumping too much air overdistends the
lung, leading to ventilator-induced lung injury (VILI).
Doctors currently use small amounts of air (low tidal
volume) to protect against VILI. But low tidal volumes can lead to
progressive closure of the lungs’ air cells, called alveoli, reducing the
lung’s ability to exchange gases. One way to reverse closure of the alveoli
is to periodically give a more robust puff of air, known as deep inflation.
A new study in the online edition of the American
Journal of Physiology-Lung Cellular and Molecular Physiology shows that
low tidal volume combined with periodic deep inflation provides the best
balance between keeping the lung open and preventing VILI in mice. And,
using mice, these researchers have shown for the first time that although
deep inflation is necessary, it can be overdone.
“There is still a lot of controversy and uncertainty
about how best to ventilate the lung,” said the study’s senior author, Jason
HT Bates of the University of Vermont. “One controversy is whether deep
inflations, the “sighs” that each of us takes periodically, should ever be
given, and if so, how frequently.”
Researchers find optimal
range
“This study demonstrates that an optimal frequency
range of deep inflation delivery exists, at which point the potentially
injurious effects of overdistention are outweighed by the protective
benefits of maintaining a predominantly open lung,” wrote Gilman B. Allen,
Benjamin T. Suratt, Lisa Rinaldi, Joseph M. Petty and Bates in the AJP-Lung
paper entitled “Choosing the frequency of deep inflation in mice: balancing
recruitment against ventilator-induced lung injury.”
Allen, a medical doctor with Fletcher Allen Health Care
and the University of Vermont department of medicine, has treated patients
on ventilation. Bates is a University of Vermont department of medicine
researcher interested in lung physiology.
Ventilators are commonly used in hospital intensive
care units with a variety of patients, including those with acute lung
injury, acute respiratory distress syndrome, pneumonia, septic shock,
trauma, aspiration of vomit and chemical inhalation. As a result of these
conditions, fluid can build up in the lungs, blocking the alveoli. This
causes the body to mount an inflammatory response, which injures the lung’s
epithelial lining, Bates said. At that point, doctors provide mechanical
ventilation in the intensive care unit until the body heals itself.
Bates explains the difficulty of treating the injured
lung this way: “Imagine you have two balloons which you fill by pumping in
air. Now imagine you have only one balloon, and you must drive the same
volume of air into the one balloon as you did into two,” Bates explained.
The same thing happens in the lungs. When parts of the lungs are no longer
working, it places greater pressure on the portions of the lung that are
working, with the remaining lung handling the air pressure that two lungs
had handled.
Doctors consider tidal volume (the amount of air an
individual normally inhales and exhales), deep inflation frequency (the
number of deep breaths given) and PEEP (positive end-expiratory pressure),
which helps keep lungs from collapsing by preventing the airways from
emptying completely. PEEP also helps improve gas exchange within the lungs.
Low tidal volume, varied
sigh rate
The researchers divided mice into three experimental
groups. All three groups received PEEP and low tidal volume air. Each group
was ventilated for two hours. The experimental groups differed according to
how many deep inflations they received. They were as follows:
-
HV (high volume) received one deep inflation each breath
-
LV (low volume) received two deep inflations each hour
-
LVDI (low volume deep inflation) received two deep
inflations each minute
In addition, there were two control groups -- a
surgical sham, which received no ventilation, and a group that received deep
inflation every breath and no PEEP.
The study found that:
-
The lungs of the mice given two big breaths every minute (LVDI)
remained more open and functioned better than the LV and HV.
-
The lungs of the mice that received only two deep breaths
per hour (LV) became stiff and portions of the lungs collapsed. However,
lung function returned briefly to normal when the mice received their
infrequent deep inflations. This suggests that the lungs self-repair
after the deep inflation, at least over the course of the first two
hours.
-
The lungs of the mice that received deep inflation every
breath (HV) suffered overdistention injury to their lungs. This group
was akin to a high tidal volume group, once again demonstrating that low
tidal volume is safer.
-
The control group that received high tidal volume but no
PEEP showed the highest evidence of injury, even higher than the high
tidal volume group. This indicates that PEEP helps reduce the negative
effects of frequent deep inflation.
“We demonstrated it’s possible to give deep breaths too
frequently and too seldom,” Bates explained. The middle ground -- two deep
inflations per minute -- provides the most benefit to the mice we studied
without injuring the lungs, he said.
“We conclude that frequent deep inflation can safely
improve gas exchange and lung mechanics and may confer protection from
biotrauma,” the authors wrote. “Differences between LVDI and HV suggest that
an optimal frequency range of deep inflation exists, within which the
benefits of maintaining an open lung outweigh injury incurred from
over-distention.”
Next step
“Our findings have obvious implications for the
recruitment of the injured human lung during low tidal ventilation,” the
authors wrote. “However, extrapolating our results to the clinical situation
must be done guardedly. In the present study we employed uninjured mice,
whereas it is known that the injured lung is more prone to atelectasis
(collapse) than a normal lung.”
Bates’ team hopes to move to a human trial in the near
future, now that they have established that deep inflation is beneficial and
can be delivered with an optimal frequency.
Source
“Choosing the frequency of deep inflation in mice:
balancing recruitment against ventilator-induced lung injury,” by Gilman B.
Allen, Benjamin T. Suratt, Lisa Rinaldi and Joseph M. Petty and Jason HT
Bates, Vermont Lung Center, Department of Medicine, University of Vermont,
Burlington. Allen, Suratt and Bates are also affiliated with the Fletcher
Allen Health Care, Burlington. The study appears in the online edition of
American Journal of Physiology Lung Cellular and Molecular Physiology
published by The American Physiological Society.
Funding
The study was funded by grants from the National
Institutes of Health’s Centers of Biomedical Research Excellence and
GlaxoSmithKline.
Editor’s notes
The media may obtain a copy of
Allen et al. by contacting
Christine Guilfoy, American Physiological Society, (301) 634-7253 or
cguilfoy@the-aps.org.
Want to learn the latest on lung disease research?
Consider attending the APS conference examining how genomics, proteomics and
bioinformatics are driving new discoveries about lung disease. Researchers
and clinicians will examine how to use this information to benefit patients
at “Physiological Genomics and Proteomics of Lung Disease,” Nov. 2-5, Fort
Lauderdale, FL. Allen Cowley Jr., editor of Physiological Genomics, and
David A. Schwartz, NIH, are featured speakers.
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