A Preliminary Study of Cardiopulmonary Resuscitation by Circumferential Compression of the Chest with Use of a Pneumatic Vest
Henry R. Halperin, Joshua E. Tsitlik, Mark Gelfand, Myron L. Weisfeldt, Kreg G. Gruben, Howard R. Levin, Barry K. Rayburn, Nisha C. Chandra, Carol Jack Scott, Billie J. Kreps, Cynthia O. Siu, and Alan D. Guerci
Background More than 300,000 people die each year of cardiacarrest. Studies have shown that raising vascular pressures duringcardiopulmonary resuscitation (CPR) can improve survival andthat vascular pressures can be raised by increasing intrathoracicpressure.
Methods To produce periodic increases in intrathoracic pressure,we developed a pneumatically cycled circumferential thoracicvest system and compared the results of the use of this systemin CPR (vest CPR) with those of manual CPR. In phase 1 of thestudy, aortic and right-atrial pressures were measured duringboth vest CPR (60 inflations per minute) and manual CPR in 15patients in whom a mean (±SD) of 42 ±16 minutesof initial manual CPR had been unsuccessful. Vest CPR was alsocarried out on 14 other patients in whom pressure measurementswere not made. In phase 2 of the study, short-term survivalwas assessed in 34 additional patients randomly assigned toundergo vest CPR (17 patients) or continued manual CPR (17 patients)after initial manual CPR (duration, 11 ±4 minutes) hadbeen unsuccessful.
Results In phase 1 of the study, vest CPR increased the peakaortic pressure from 78 ±26 mm Hg to 138 ±28 mmHg (P<0.001) and the coronary perfusion pressure from 15±8 mm Hg to 23 ±11 mm Hg (P<0.003). Despiteprolonged unsuccessful manual CPR, spontaneous circulation returnedwith vest CPR in 4 of the 29 patients. In phase 2 of the study,spontaneous circulation returned in 8 of the 17 patients whounderwent vest CPR as compared with only 3 of the 17 patientswho received continued manual CPR (P = 0.14). More patientsin the vest-CPR group than in the manual-CPR group were alive6 hours after attempted resuscitation (6 of 17 vs. 1 of 17)and 24 hours after attempted resuscitation (3 of 17 vs. 1 of17), but none survived to leave the hospital.
Conclusions In this preliminary study, vest CPR, despite itslate application, successfully increased aortic pressure andcoronary perfusion pressure, and there was an insignificanttrend toward a greater likelihood of the return of spontaneouscirculation with vest CPR than with continued manual CPR. Theeffect of vest CPR on survival, however, is currently unknownand will require further study.
Source Information
From the Peter Belfer Cardiac Mechanics Laboratory, Cardiology Division, Department of Medicine (H.R.H., J.E.T., M.G., M.L.W., H.R.L., B.K.R., N.C.C., B.J.K., C.O.S., A.D.G.), the Department of Biomedical Engineering (H.R.H., J.E.T., K.G.G.), and the Department of Emergency Medicine (C.J.S.), Johns Hopkins Medical Institutions, Baltimore.
Address reprint requests to Dr. Halperin at the Cardiology Division, Johns Hopkins Hospital, 600 N. Wolfe St., Baltimore, MD 21205.
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