Physiologic validation of the compensatory reserve metric obtained from pulse oximetry: A step towards advanced medical monitoring on the battlefield

Richard T Roden; Kevin L Webb; Wyatt W Pruter; Ellen K Gorman; David R Holmes 3rd; Clifton R Haider; Michael J Joyner; Timothy B Curry; Chad C Wiggins; Victor A Convertino

doi:10.1097/TA.0000000000004377

Physiologic validation of the compensatory reserve metric obtained from pulse oximetry: A step towards advanced medical monitoring on the battlefield

J Trauma Acute Care Surg. 2024 May 15. doi: 10.1097/TA.0000000000004377. Online ahead of print.

Authors

Richard T Roden¹, Kevin L Webb², Wyatt W Pruter², Ellen K Gorman², David R Holmes 3rd³, Clifton R Haider³, Michael J Joyner², Timothy B Curry², Chad C Wiggins, Victor A Convertino⁴

Affiliations

¹ Mayo Clinic Alix School of Medicine, Rochester, MN.
² Department of Anesthesiology & Perioperative Medicine, Mayo Clinic; Rochester, MN.
³ Department of Physiology and Biomedical Engineering, Mayo Clinic; Rochester, MN.
⁴ Battlefield Health & Trauma Center for Human Integrative Physiology, US Army Institute of Surgical Research; JBSA Fort Sam Houston; San Antonio, TX.

PMID: 38745348
DOI: 10.1097/TA.0000000000004377

Abstract

Background: The Compensatory Reserve Metric (CRM) provides a time sensitive indicator of hemodynamic decompensation. However, its in-field utility is limited due to the size and cost-intensive nature of standard vital sign monitors or photoplethysmographic volume-clamp (PPGVC) devices used to measure arterial waveforms. In this regard, photoplethysmographic measurements obtained from pulse oximetry (PPGPO) may serve as a useful, portable alternative. This study aimed to validate CRM values obtained using PPGPO.

Methods: Forty-nine healthy adults (25 females) underwent a graded lower body negative pressure (LBNP) protocol to simulate hemorrhage. Arterial waveforms were sampled using PPGPO and PPGVC. The CRM was calculated using a one-dimensional convolutional neural network. Cardiac output and stroke volume were measured using PPGVC. A brachial artery catheter was used to measure intraarterial pressure. A 3-lead ECG was used to measure heart rate. Fixed-effect linear mixed models with repeated measures were used to examine the association between CRM values and physiologic variables. Log-rank analyses were used to examine differences in shock determination during LBNP between monitored hemodynamic parameters.

Results: The median LBNP stage reached was 70 mmHg (Range: 45-100 mmHg). Relative to baseline, at tolerance there was a 47±12% reduction in stroke volume, 64±27% increase in heart rate, and 21±7% reduction in systolic blood pressure (P<0.001 for all). CRM values obtained with both PPGPO and PPGVC were associated with changes in heart rate (P<0.001), stroke volume (P<0.001), and pulse pressure (P<0.001). Furthermore, they provided an earlier detection of hemodynamic shock relative to the traditional metrics of shock index (P<0.001 for both), systolic blood pressure (P<0.001 for both), and heart rate (P=0.001 for both).

Conclusion: The CRM obtained from PPGPO provides a valid, time-sensitized prediction of hemodynamic decompensation, opening the door to provide military medical personnel noninvasive in-field advanced capability for early detection of hemorrhage and imminent onset of shock.

Level of evidence: Diagnostic Tests or Criteria, Level IV.

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