Pushing on the chest to simulate the hearts rhythmic pumping action is an essential part of cardiopulmonary resuscitation after cardiac arrest. In recent decades, manufacturers have developed several mechanical devices that claim to perform CPR more effectively than human efforts alone.
However, the first systematic review of randomized clinical trials comparing mechanical to manual chest compressions has failed to demonstrate that one is superior to the other.
The only large recent study, in fact, found that patients treated with a mechanical device fared more poorly. Yet, problems in how the study took place might explain these unexpected results, the reviewers said.
Based on the evidence as it currently stands, its difficult to say for sure whether these devices harm or benefit, said Steven C. Brooks, MD, assistant professor of medicine at University of Toronto and lead review author. There is a need for more studies.
The reviewers analyzed data from four randomized controlled trials, involving a total 868 patients.
The review appears in the latest issue of The Cochrane Library, a publication of the Cochrane Collaboration, an international organization that evaluates medical research. Systematic reviews draw evidence-based conclusions about medical practice after considering both the content and quality of existing medical trials on a topic.
CPR guidelines from the American Heart Association and other organizations increasingly emphasize the importance of performing chest compressions properly to optimize survival after cardiac arrest. But repeated studies suggest that fatigue, distraction and other demands of the resuscitation process, such as breathing support, make it difficult for even trained rescuers to deliver compressions deeply and rapidly enough, and without interruption.
Several manufacturers have developed devices using bands or pistons to rhythmically compress the chest, in an attempt to overcome these problems.
Although animal research, anecdotal reports and studies of small series of patients suggest that they are more effective than manual chest compression, a systematic review of quality clinical research had not yet been done, Brooks said.
The studies findings were inconsistent: three small studies suggested that mechanical devices were beneficial, and the one large study found harm. Taken together, they provided insufficient evidence to draw meaningful conclusions, the authors wrote.
The large study compared 767 patients who had cardiac arrest outside the hospital and underwent CPR with chest compressions either applied manually or delivered automatically by a device using a band around the chest.
In the study, 3.1 percent of the patients receiving mechanical chest compressions survived to hospital discharge with no or relatively mild signs of brain damage, compared with 7.5 percent of those who had manual compressions.
There were major methodological issues that might explain why [this study] came out with such a different answer than what was expected from previous small studies and from physiological studies, Brooks said.
These included the fact that the finding of harm depended on results from a single study site, where the CPR procedure was changed midway through the study, and that significantly more patients in the mechanical group were thin or morbidly obese than in the manual group.
More important, patients receiving mechanical compression waited longer for defibrillation, an electrical shock delivered to restart the heart, compared to the manual group. It is likely that the use of a mechanical device delayed compressions, Brooks said.
Resuscitation in the field is commonly done in tight spaces and needs to be like a well- choreographed ballet, he said. One could hypothesize that the machine would work well when you get it on the chest properly, but the devils in the details, how fast you can deploy the device and incorporate it into the ballet of resuscitation.
Robert E. OConnor, M.D., chair of emergency medicine at University of Virginia, called the review extremely well done, and said that even though it didnt completely answer the question, it gives future investigators some direction for CPR studies in general.
He proposed that the question is not whether the devices work in the laboratory they do but whether you can get them on quickly enough without interrupting chest compressions for any length of time. You pay a price for applying any device. The question is whether the price is worth it.
Chest compression devices are very attractive to anyone who performs CPR, OConnor said. And there may be some use for them, particularly in EMS agencies with limited numbers of rescuers. But you really have to pay strict attention to timing.
Brooks said that to his thinking, his findings do not indicate that agencies should stop using chest compression devices, but the evidence suggests the need for caution, and a focus on how the device is deployed quickly, and with minimum interruption.
He said that a much larger international study comparing manual and mechanical chest compressions, scheduled for completion in 2012, should provide more definitive answers.
Brooks SC, et al. Mechanical versus manual chest compressions for cardiac arrest (Review). Cochrane Database of Systematic Reviews 2011, Issue 1.