Muscle Activity during the Performance of CPR in Simulated Microgravity and Hypogravity

Rafael Reimann Baptista; Thiago Susin; Mariana Dias; Nicholas Corrêa; Ricardo Cardoso; Thais Russomano

American Journal of Medical and Biological Research. 2015, 3(4), 82-87
DOI: 10.12691/AJMBR-3-4-1

Original Research

Muscle Activity during the Performance of CPR in Simulated Microgravity and Hypogravity

Rafael Reimann Baptista^1,, Thiago Susin¹, Mariana Dias¹, Nicholas Corrêa¹, Ricardo Cardoso¹ and Thais Russomano¹

¹Microgravity Center – Pontifical Catholic University of Rio Grande do Sul, Porto Alegre, Brazil.

Pub. Date: June 03, 2015

Full Text PDF

Cite this paper

Rafael Reimann Baptista, Thiago Susin, Mariana Dias, Nicholas Corrêa, Ricardo Cardoso and Thais Russomano. Muscle Activity during the Performance of CPR in Simulated Microgravity and Hypogravity. American Journal of Medical and Biological Research. 2015; 3(4):82-87. doi: 10.12691/AJMBR-3-4-1

Abstract

Cardiopulmonary resuscitation (CPR) is a series of resuscitation actions that improve the survival chances after a cardiac arrest, maintaining tissue perfusion through sternal compressions. The aim of this study was to clarify potential differences in upper body muscle activity related to CPR in microgravity and hypogravity (Mars gravitational field). Thirty healthy male volunteers each performed 3 sessions of 30 external chest compressions (ECCs) on a mannequin, during which time the muscle activity of the pectoralis major, triceps brachii and rectus abdominis were recorded via superficial electromyography. Hypogravity and microgravity were simulated by means of a body suspension device and a counterweight system, to which the volunteer was connected via a harness. The standard terrestrial (1G) CPR position was adopted in simulated hypogravity, and the Evetts–Russomano method was used in simulated microgravity. Heart rate and perceived exertion were also measured via Borg scale. No significant difference was found between the ECCs per minute and per set of compressions when performed at 1G and in simulated hypogravity. However, the mean depth achieved during compressions showed a significant difference in hipogravity. After 3 sets of 30 ECCs, mean heart rate showed an increase from rest values to those obtained from the 3 gravitational fields, and also from 1G to microgravity, but not from 1G to hypogravity. Mean of perceived exertion presented a significant increase from 1G to hypograviy and to microgravity. Muscle activation during the performance of CPR at 1G and hypogravity was significantly higher for the rectus abdominis. All muscles were more active during CPR in microgravity when compared with 1G. These findings suggest that the rescuer should be physically well trained in order to deliver adequate CPR in extraterrestrial environments. The physical training should aim to improve muscular endurance and cardiorespiratory capacity to increase effectiveness of the rescuer emergency assistance.

Keywords

cardiopulmonary resuscitation, hypogravity, microgravity, body suspension, electromyography

Copyright

This work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]	Sasson, C.M.A., Rogers, J., Dahl, A.L.K., “Predictors of survival from out-of-hospital cardiac arrest: a systematic review and meta-analysis”, Circ Cardiovasc Qual Outcomes, (3). 63-81. 2010.

[2]	Sayre, M.R., Koster, R.W., Botha, M., Cave, D.M., Cudnik, M.T., Handley, A.J., Hatanaka, T., Hazinski, M.F., Jacobs, I., Monsieurs, K, Morley, P.T., Nolan, J.P., Travers, A.H., “Part 5: adult basic life support: 2010 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science With Treatment Recommendations”, Circulation, 122 (2). 298-324. 2010.

[3]	Go, A.S., Mozaffarian, D., Roger, V.L., Benjamin, E.J., Berry J.D., Borden, W.B., Bravata, D.M., Dai, S., Ford, E.S., Fox, C.S., Franco, S., Fullerton, H.J., Gillespie, C., Hailpern, S.M., Heit, J.A., Howard, V.J., Huffman, M.D., Kissela, B.M., Kittner, S.J., Lackland, D.T., Lichtman, J.H., Lisabeth, L.D., Magid, D., Marcus, G.M., Marelli, A., Matchar, D.B., McGuire, D.K., Mohler, E.R., Moy, C.S., Mussolino, M.E., Nichol, G., Paynter, N.P., Schreiner, P.J., Sorlie, P.D., Stein, J., Turan, T.N., Virani, S.S., Wong, N.D., Woo D., Turner, M.B., “Heart disease and stroke statistics-2013 update: a report from the American Heart Association”, Circulation, 127. 6-245. 2013.

[4]	Calder, A., Nijar, J., Scarpa, P., “Use of ultrasound for diagnosis in microgravity: comparative survey of NASA flightsurgeon and consultant radiologist opinions”, Aviation, Space, and Environmental Medicine, 78 (3), p-134. 2007.

[5]	Platts, S.H., Stenger, M.B., Philips, T.R., Arzeno, N.M., Brown, A.K., Levin, B., Summers, R., “Evidence based review: risk of cardiac rhythm problems during space flight”, NASA publication, 2010.

[6]	Fritsch-Yelle, J.M., Leuenberger, U.A., D'Aunno, D.S., Rossum, A.C., Brown, T.E., Wood, M.L., Josephson, M.E., Goldberger, A.L., “An episode of ventricular tachycardia during long-duration spaceflight”, American Journal of Cardiology, (81). 1391-2. 1998.

[7]	Perhonen, M.A., Franco, F., Lane, L.D., Buckey, J.C., Blomgvist, C.G., Zerwekh, J.E., Peshock, R.M., Weatherall, P.T., Levine, B.D., “Cardiac atrophy after bed rest and spaceflight”, Journal of Applied Physiology, 91 (2). 645-53. Aug. 2001.

[8]	Huikuri, H.V., Pekka, M.J.R, Moerch-Joergensen, R., Hartikainen, J., Virtanen, V., Boland, J., Anttonen, O., Hoest, N., Boersma, L.V.A., Platou, E.S., Messier, M.D., Bloch-Thomsen, P., “Prediction of fatal or near-fatal cardiac arrhythmia events in patients with depressed left ventricular function after an acute myocardial infarction”, European Heart Journal, 30. 689-698. 2009.

[9]	Sides, M.B., Vernikos, J., Convertino, V.A., Stepanek, J., Tripp, L.D., Draeger, J., Hargens, A.R., Kourtidou-Papadeli, C., Pavy-LeTraon, A., Russomano, T., Wong, J.Y., Buccello, R.R., Lee, P.H., Nangalia, V., Saary, M.J., “The Bellagio report: cardiovascular risks of spaceflight: implications for the future of space travel”, Aviation, Space, and Environmental Medicine, 76. 877-895. 2005.

[10]	Jay, G.D., Lee, P.H.U., Goldsmith, H., Battat, J., Maurer, J., Suner, S., “CPR effectiveness in microgravity: comparison of three positions and a mechanical device”, Aviation, Space, and Environmental Medicine, 74, 1183-1189. 2003.

[11]	Johnston, S.L., Campbell, M.R., Billica, R.D., Gilmore, S.M., “Cardiopulmonary resuscitation in microgravity: efficacy in the swine during parabolic flight”, Aviation, Space, and Environmental Medicine, 75. 546-550. 2004.

[12]	Evetts, S.N., Evetts, L.M., Russomano, T., Castro J.C., Ernsting, J., “Basic life support in microgravity: evaluation of a novel method during parabolic flight”, Aviation, Space, and Environmental Medicine, 76. 506-510. 2005.

[13]	Rehnberg, L., Russomano, T., Falcão, F., Campos, F., evetts, S.N., “Evaluation of a novel basic life support method in simulated microgravity”, Aviation, Space, and Environmental Medicine, 82. 104-10. 2011.

[14]	Borg, G., “Perceived exertion as an indicator of somatic stress”, Scandinavian Journal of Rehabilitation Medicine, 2. 92-98. 1970.

[15]	Merletti, R., Hermens, H., “Introduction to the special issue on the SENIAM european concerted action”, Journal of Electromyography and Kinesiology, 10. 283-286. 2000.

[16]	Dalmarco, G., Calder, A., Falcão F., Azavedo, D.F.G., Sarkar, S., Evetts, S., Moniz, S., Russomano, T., “Evaluation of external cardiac massage performance during hypogravity simulation”, Conference proceedings: Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 1. 2904-7. 2006.

[17]	Krygiel, R.G., Waye, A.B., Baptista, R.R., Heidner, G.S., Rehnberg, L., Russomano, T., “The Evaluation of Upper Body Muscle Activity During the Performance of External Chest Compressions in Simulated Hypogravity”, Life Sciences in Space Research, 1. 60-66. 2014.

[18]	“American Heart Association (AHA) Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care-IV”, Circulation, 112. 19-34. 2005.

[19]	Billica, R., Gosbee, J., Krupa, D., “Evaluation of cardiopulmonary resuscitation techniques in microgravity”, Medical Evaluations on the KC-135: 1990 flight report summary. 91. 163-83. 1990.

[20]	Gallo Jr, L., Maciel, B.C., Marin Neto, J.A., Martins, L.E.B., “Sympathetic and parasympathetic changes in heart rate control during dynamic exercise induced by endurance training in man”, Brazilian Journal of Medical and Biological Research, 22. 631-43. 1989.

[21]	Greenleaf, J., “Exercise Contermeasures for Bed-Rest Deconditioning (1986): Final Report”, NASA technical Memorandum 103987, p-215. Jun. 1993.

[22]	Crowell, B., “Newtonian Physics. California: Light and Matter”, 12. 124-57. 2010.

[23]	Tsou, J., Chi, C., Hsu, R.M., Su, F., “Electromyography activity of selected trunk muscles in rescuers during cardiopulmonary resuscitation”, International Society of Biomechanics Congress, Taipei. Taiwan. 1^st-5^th Jul. 2007.

[24]	Waye, A.B., Krygiel, R.G., Susin, T.B., Baptista, R., Rehnberg, L., Heidner, G.S., Campos, F., Falcão, F.P., Russomano, T., “Evaluation of upper body muscle activity during cardiopulmonary resuscitation performance in simulated microgravity”, Advances in space research, 52. 971-978. 2013.