Trimodal wireless intramuscular device detects muscle pressure, flow, and oxygenation changes in porcine model of lower extremity compartment syndrome

Purpose Compartment syndrome remains difficult to diagnose early in its clinical course. Pressure transducer catheters have been used to directly measure intracompartmental pressure (ICP), but this method is unreliable, with a false positive rate of 35%. We have previously used intramuscular near in...

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Bibliographic Details
Published in:European journal of orthopaedic surgery & traumatology 2024-08, Vol.34 (6), p.2997-3004
Main Authors: Westman, Amanda M., Ribaudo, Joseph, Seo, Seung Gi, Moritz, William, Tatman, Lauren M., Jin, Sung Hun, Kim, Seungyeob, Oh, Seyong, Rogers, John A., Pet, Mitchell A.
Format: Article
Language:English
Subjects:
Animals
Compartment syndrome
Compartment Syndromes - diagnosis
Compartment Syndromes - physiopathology
Disease Models, Animal
Lower Extremity - blood supply
Lower Extremity - physiopathology
Medicine
Medicine & Public Health
Microcirculation - physiology
Muscle, Skeletal - blood supply
Muscle, Skeletal - metabolism
Muscle, Skeletal - physiopathology
Original Article
Oxygen - blood
Oxygen - metabolism
Oxygen Saturation - physiology
Pathophysiology
Pressure
Proof of Concept Study
Regional Blood Flow - physiology
Spectroscopy, Near-Infrared - instrumentation
Spectroscopy, Near-Infrared - methods
Surgical Orthopedics
Swine
Traumatic Surgery
Wireless Technology - instrumentation
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Summary:Purpose Compartment syndrome remains difficult to diagnose early in its clinical course. Pressure transducer catheters have been used to directly measure intracompartmental pressure (ICP), but this method is unreliable, with a false positive rate of 35%. We have previously used intramuscular near infrared spectroscopy to detect changes in tissue oxygen saturation (StO 2 ) in response to increasing ICP using a novel implantable probe. However, measuring StO 2 may not be sufficient to identify CS in the clinical setting. The pathophysiology of CS consists of increased ICP, leading to decreased tissue perfusion, and resulting in reduced tissue oxygenation. More clinically useful information may come from the integration of multiple data streams to aid in the diagnosis of CS. In this study, we present a novel, intramuscular probe capable of simultaneous measurement of ICP, StO 2 , and microvascular blood flow in a porcine model of ACS. Methods Proof of concept for this device is demonstrated in a porcine lower extremity balloon compression model of ACS. Pressure was maintained for 20 min (short-term) or 3 h (long-term) before the balloon volume was removed. Results In both short- and long-term experiments, as ICP increased with increasing balloon volume, the novel multimodal sensor simultaneously and reliably detected pressure elevation and corresponding reversible reductions in microvascular flow rate and tissue oxygenation. Conclusion This novel trimodal device simultaneously measured the elevated ICP, decreased perfusion, and tissue ischemia of evolving ACS, substantiating our basic understanding of CS pathophysiology.
ISSN:1432-1068
1633-8065
1432-1068
DOI:10.1007/s00590-024-04023-4