BACKGROUND: If a cardiac arrest occurs in microgravity, the aim of current emergency procedures is to treat the patient using a medical restraint system within 2 min. The patient may require treatment while medical equipment is being deployed. The capability for one person, unaided, to successfully perform cardiopulmonary resuscitation (CPR) is, therefore, of paramount importance. A new technique has been developed whereby the practitioner encircles the thorax of the patient with his/her legs to restrain the patient to allow CPR to be performed in microgravity. METHOD: Two investigators performed both this method (during parabolic microgravity) and traditional CPR (at +1 Gz) on an instrumented CPR mannequin. The mannequin was modified to ensure accurate chest compression and ventilation measurements during microgravity. RESULTS: The mean (+/-SE) depth and rate of chest compression were 44.0+/-4.99 mm and 68.3+/-17.0 compressions x min(-1) respectively. Although the mean microgravity rate of compression proved significantly less (p < 0.05) than the +1 Gz mean (97.1+/-3.4 compressions x min(-1)), chest compression depth did not differ (p > 0.05) from +1 Gz measures (43.6+/-0.59 mm). The mean (+/-SE) microgravity tidal volume (VT) was 491+/-50.4 ml, which also did not differ (p > 0.05) from +1 Gz values (507.6+/-11.5 ml). DISCUSSION: Although difficulties in performing this method during parabolic flight primarily affected compression rate, it may be possible to conduct basic life support using this technique in any microgravity environment.
BACKGROUND: If a cardiac arrest occurs in microgravity, the aim of current emergency procedures is to treat the patient using a medical restraint system within 2 min. The patient may require treatment while medical equipment is being deployed. The capability for one person, unaided, to successfully perform cardiopulmonary resuscitation (CPR) is, therefore, of paramount importance. A new technique has been developed whereby the practitioner encircles the thorax of the patient with his/her legs to restrain the patient to allow CPR to be performed in microgravity. METHOD: Two investigators performed both this method (during parabolic microgravity) and traditional CPR (at +1 Gz) on an instrumented CPR mannequin. The mannequin was modified to ensure accurate chest compression and ventilation measurements during microgravity. RESULTS: The mean (+/-SE) depth and rate of chest compression were 44.0+/-4.99 mm and 68.3+/-17.0 compressions x min(-1) respectively. Although the mean microgravity rate of compression proved significantly less (p < 0.05) than the +1 Gz mean (97.1+/-3.4 compressions x min(-1)), chest compression depth did not differ (p > 0.05) from +1 Gz measures (43.6+/-0.59 mm). The mean (+/-SE) microgravity tidal volume (VT) was 491+/-50.4 ml, which also did not differ (p > 0.05) from +1 Gz values (507.6+/-11.5 ml). DISCUSSION: Although difficulties in performing this method during parabolic flight primarily affected compression rate, it may be possible to conduct basic life support using this technique in any microgravity environment.
Authors: Jochen Hinkelbein; Steffen Kerkhoff; Christoph Adler; Anton Ahlbäck; Stefan Braunecker; Daniel Burgard; Fabrizio Cirillo; Edoardo De Robertis; Eckard Glaser; Theresa K Haidl; Pete Hodkinson; Ivan Zefiro Iovino; Stefanie Jansen; Kolaparambil Varghese Lydia Johnson; Saskia Jünger; Matthieu Komorowski; Marion Leary; Christina Mackaill; Alexander Nagrebetsky; Christopher Neuhaus; Lucas Rehnberg; Giovanni Marco Romano; Thais Russomano; Jan Schmitz; Oliver Spelten; Clément Starck; Seamus Thierry; Rochelle Velho; Tobias Warnecke Journal: Scand J Trauma Resusc Emerg Med Date: 2020-11-02 Impact factor: 2.953
Authors: Thais Russomano; Justin H Baers; Rochelle Velho; Ricardo B Cardoso; Alexandra Ashcroft; Lucas Rehnberg; Rodrigo D Gehrke; Mariana K P Dias; Rafael R Baptista Journal: Extrem Physiol Med Date: 2013-04-01