Diagnosing acute compartment syndrome—where have we got to?

Measurement of the partial pressure of oxygen has been investigated in canine models where ACS had been induced [42, 43], with promising results. Doro et al. measured the intramuscular partial pressure of oxygen in adult beagles to be 62–65 mmHg before creation of compartment syndrome. They found that a partial pressure of oxygen of less than 30 mmHg had a 100% sensitivity (95% CI 72–100%) and 100% specificity (95% CI 69–100%) [43]. Feasibility studies looking at direct measurement of intramuscular oxygen pressures in humans are available [44, 45], although study numbers are small.

Oxygen saturation can also be monitored non-invasively, as shown by Reisman et al. [46], Shuler et al. [47, 48] and Schmidt et al. [36] in their trials using near-infrared spectroscopy (NIRS) to measure oxygen saturation of muscle.

The principals of measuring blood flow are based on the fact that as a response to trauma, the body will increase the blood flow to the site of injury. If this is absent, it could be indicative of ACS and would also result in desaturated haemoglobin and myoglobin [49]. NIRS is a non-invasive method for assessing levels of oxygenated muscle haemoglobin and myoglobin. When blood flow is decreased, a reduction in local oxygen saturation and muscle oxygen tension can be seen. It is not new technology, having been used over 40 years ago to monitor cerebral and myocardial oxygen sufficiency [50]. This was achieved through transillumination of the heart or brain, with photon transmission through the organ at wavelengths varying from 740 to 860 nm focused to cytochrome aa3. Its potential role in diagnosing ACS is significantly more recent. NIRS was proposed by Reisman et al. [46] as a non-invasive technique for assessing blood flow to rule out ACS. The technology is similar to measuring oxygen saturations in subcutaneous tissues, something that is done routinely in bedside monitoring of patients.

In a porcine model of ACS, near-infrared spectroscopy provided a reliable, sensitive measure of tissue oxygenation that directly correlated with a simulated increase in tibial compartmental pressure and a decrease in tibial intracompartmental perfusion pressure [51]. In 2007, a paediatric case report utilised NIRS in the diagnosis of ACS in a one month old infant, with a NIRS value of 15% in the involved limb versus 40–50% in the uninvolved limb [52]. In patients with ACS, Shuler et al. found NIRS values from at least one compartment to be more than 3% below an uninjured control compartment [53]. They advocated simultaneous monitoring of the same compartment on the contralateral limb in order to provide a control. This was because NIRS values vary significantly between individuals and indeed can vary within compartments over time, but the simultaneous difference between uninjured ‘like’ compartments varies less. Just as for pressure monitoring, continuous assessment of tissue oxygenation with NIRS would theoretically be an ideal means to document the onset or progression of tissue hypoxia, alerting clinicians so that timely intervention follows. However, a study by Schmidt et al. found poor reliability in obtaining continuous NIRS data not only in the injured limb, but even in the control (reference) limb, raising questions about the value of continual NIRS in diagnosing ACS [54]. Therefore, the literature is somewhat confounding. Whilst NIRS has the potential to offer the ability to objectively measure tissue perfusion in a non-invasive and continuous manner, additional studies are required to validate whether or not NIRS has a clinical role in ACS monitoring. Other limitations of NIRS include limited depth of tissue penetration and the tendency for skin colour and subcutaneous bruising/haematomas to adversely affect readings.

In 1989, ultrasound was used to assess for variations in compartmental geometry and echogenicity in relation to pressure, and whilst echogenicity increased as pressure increased, correlation and reproducibility were felt to be poor [55]. More recently, ultrasound has been used to assess compartment elasticity when subjected to external compression, using a standardised pressure. So far it has only been assessed in vitro [56] and in cadaveric models [57] by Sellei et al.

The evolution of pulsed phased-locked loop (PPLL) ultrasound shows greater promise. For the diagnosis of ACS, PPLL measures fascial wall displacement in correlation with arterial pulsations, with the magnitude of arterial pulsations and subsequent perfusion diminishing as compartmental pressure rises. In a cadaveric study, Lynch et al. showed PPLL to detect compartmental changes resulting from pressure changes of 1 mmHg [58]. Wiemann et al. collected data from nine  patients with simulated compartment tamponade and three  patients with ACS and demonstrated a linear correlation between PPLL and intramuscular pressure [59]. Similarly, in a simulated ACS study, Lee et al. showed a statistically significant correlation between PPLL data and increasing chamber/intramuscular pressure [49]. Interestingly, they also found PPLL to perform superiorly to NIRS, due to less subject to subject variability. Having said this, the data in the literature is from small studies performed in a predominantly non-clinical simulated environment, and so considerable research is required before this method could be used clinically.

Photoplethysmography has also been trialled as a way of measuring increasing blood flow by Challa et al. This technique uses a light-emitting diode to shine light onto skin, and a photodetector can monitor and record the attenuation of the reflected light, which is directly related to blood flow [60]. There is no current role to support its clinical use in the diagnosis of ACS. Laser Doppler flowmetry and scintigraphy also provide methods for assessing local perfusion. In the diagnosis of chronic compartment syndrome, both techniques have been found to be viable [61, 62]. In scintigraphy, time-consuming scans, the lack of specificity in a traumatised limb and the inability to perform repeated/continuous examinations make it unsuitable for diagnosing ACS. The use of laser Doppler flowmetry in diagnosing ACS is yet to be evaluated.

Doro et al. measured intramuscular glucose in 12 canine models (baseline of 158 mg/dL in control group) and found that an intramuscular glucose concentration of less than 97 mg/dL was 100% sensitive (95% CI 73–100%) and 75% specific (95% CI 40–94%), and that changes could be detected as soon as 15 minutes  after induction of compartment syndrome, when compared against a control [43]. Being able to detect changes, this quickly has huge potential; however, the authors acknowledge that the technology used in this study would need further development of glucose sensors in order for this research project to progress to human trials.

The surface pH of skeletal muscle has been confirmed to be a sensitive indicator of peripheral muscle blood flow [63]. Several methods of recording muscle pH have been used in research. Initially, it was only possible to accurately record this through muscle biopsy, making sampling and analysis time-consuming and repeat sampling unsuitable. The development of probes to measure intramuscular (IM) pH is a more recent concept. In research performed by two of the authors (AJJ and KE), a 1.8-mm glass catheter was connected to an ambulatory pH recorder to measure IM pH. In an initial study of 62 patients, its sensitivity and specificity were found to be significantly higher than intracompartmental pressure monitoring [64]. Invasive pH monitoring continues to be investigated by the senior author (AJJ), with early results indicating that IM pH monitoring has the potential to deliver a more accurate and faster method for diagnosing ACS. The outcome of a multi-centre clinical trial due to commence soon will hopefully provide further validity for this technique.

Following trauma, and after the onset of ACS, the inflammatory response leads to a rise in inflammatory biomarkers such as white cell count (WCC), erythrocyte sedimentation rate (ESR) and C-reactive protein (CRP). Additionally, creatine kinase and lactate levels rise, due to muscle breakdown and anaerobic metabolism respectively. Creatinine kinase levels of > 2000 units/L can be a warning sign of compartment syndrome in a sedated and ventilated patient [65]. Similarly, ischaemia-modified albumin (IMA) has been shown to rise with reasonable sensitivity and specificity in the presence of critical limb ischaemia; however, its role in aiding the diagnosis of ACS remains unclear [66]. Whilst the levels of these biomarkers change in association with acute compartment syndrome, at present, no serum marker has been shown to have adequate sensitivity and specificity to quantify the level of skeletal muscle ischaemia, and therefore cannot be accurately used to diagnosis acute compartment syndrome. However, the testing of regional or local biomarker levels such as intramuscular glucose and pH does offer greater potential.