Background: Modern aerial combat manouevres are an enormous challenge for human physiology [1,2].To predict the probability of a g- force induced loss of consciousness (GLOC) has been subject of numerous studies. Changes in perfusion (NIRS) and/or function of the brain (EEG, evoked potentials) have been the primary focus searching a predictor while centrifugal reallocation of blood volume is the primary cause for this blackout.To determine the peripheral bloodflow skin temperature might be used [3]. We present a pilot study using fast measurements of peripheral temperatures to predict this peripheral pooling effect. Material & Methods: 9 of the 20 subjects suffered an almost loss of consciousness (ALOC). Peripheral temperatures tended to be higher in subjects with an almost blackout.The strongest effect regarding the difference of the two groups was recorded at the upper arm (p<0.05). 20 healthy subjects were tested using a combined lower body negative pressur/tilt table.The produced push-pull effect has been used to select pilots suited to fly a forth generation jet fighter. The complete procedure was split in two phases before, one phase during and one phase after the induced push-pull effect. Recording skin III temperatures proximal and distal of the upper and lower limbs allowed to quantify the effect of a peripheral perfusion change. Results & Discussion: The probability of ALOC in this experiment could be predicted recording peripheral temperatures. Higher peripheral temperatures before the push-pull phase might be an indicator for peripheral vasodilation or a lowered sympathetic activation [4]. However, to verify this effect, the experiment has to be repeated using more subjects and different hyper-g scenarios as the short and long arm centrifuge and real aircraft manoeuvres. References: 1. Hanousek, J, P Dosel, J Cmiral, and J Petricek. "Physiological Response of Pilots to the Load of Lower Body Negative Pressure." J Gravit Physiol 4, no. 2 (1997): P33-4 2. Dosel, P, J Hanousek, J Cmiral, and J Petricek. "Physiological Response of Pilots to the LBNP-, Flight-, and Centrifuge Load." J Gravit Physiol 5, no. 1 (1998): P41-2 3. Rubinstein, E H, and D I Sessler. "Skin-surface Temperature Gradients Correlate with Fingertip Blood Flow in Humans." Anesthesiology 73, no. 3 (1990): 541-5 4. Charkoudian, Nisha. "Skin Blood Flow in Adult Human Thermoregulation: How It Works, When It Does Not, and Why." Mayo Clinic proceedings. Mayo Clinic 78, no. 5 (2003): doi:10.4065/78.5.603
Can skin temperature recordings predict GLOC? / O. Opatz, M.A. Maggioni, A.C.H. Stahn, M. Steinach, M. Von der Wiesche. ((Intervento presentato al 52. convegno DGLRM - Deutsche Gesellschaft für Luft- und Raumfahrtmedizin tenutosi a Heidelberg nel 2014.
Can skin temperature recordings predict GLOC?
M.A. Maggioni;
2014
Abstract
Background: Modern aerial combat manouevres are an enormous challenge for human physiology [1,2].To predict the probability of a g- force induced loss of consciousness (GLOC) has been subject of numerous studies. Changes in perfusion (NIRS) and/or function of the brain (EEG, evoked potentials) have been the primary focus searching a predictor while centrifugal reallocation of blood volume is the primary cause for this blackout.To determine the peripheral bloodflow skin temperature might be used [3]. We present a pilot study using fast measurements of peripheral temperatures to predict this peripheral pooling effect. Material & Methods: 9 of the 20 subjects suffered an almost loss of consciousness (ALOC). Peripheral temperatures tended to be higher in subjects with an almost blackout.The strongest effect regarding the difference of the two groups was recorded at the upper arm (p<0.05). 20 healthy subjects were tested using a combined lower body negative pressur/tilt table.The produced push-pull effect has been used to select pilots suited to fly a forth generation jet fighter. The complete procedure was split in two phases before, one phase during and one phase after the induced push-pull effect. Recording skin III temperatures proximal and distal of the upper and lower limbs allowed to quantify the effect of a peripheral perfusion change. Results & Discussion: The probability of ALOC in this experiment could be predicted recording peripheral temperatures. Higher peripheral temperatures before the push-pull phase might be an indicator for peripheral vasodilation or a lowered sympathetic activation [4]. However, to verify this effect, the experiment has to be repeated using more subjects and different hyper-g scenarios as the short and long arm centrifuge and real aircraft manoeuvres. References: 1. Hanousek, J, P Dosel, J Cmiral, and J Petricek. "Physiological Response of Pilots to the Load of Lower Body Negative Pressure." J Gravit Physiol 4, no. 2 (1997): P33-4 2. Dosel, P, J Hanousek, J Cmiral, and J Petricek. "Physiological Response of Pilots to the LBNP-, Flight-, and Centrifuge Load." J Gravit Physiol 5, no. 1 (1998): P41-2 3. Rubinstein, E H, and D I Sessler. "Skin-surface Temperature Gradients Correlate with Fingertip Blood Flow in Humans." Anesthesiology 73, no. 3 (1990): 541-5 4. Charkoudian, Nisha. "Skin Blood Flow in Adult Human Thermoregulation: How It Works, When It Does Not, and Why." Mayo Clinic proceedings. Mayo Clinic 78, no. 5 (2003): doi:10.4065/78.5.603
Pubblicazioni consigliate
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
