Aims

Compartment syndrome results from increased intra-compartmental pressure (ICP) causing local tissue ischaemia and cell death, but the systemic effects are not well described. We hypothesised that compartment syndrome would have a profound effect not only on the affected limb, but also on remote organs.

Compartment syndrome, a devastating consequence of limb trauma, is characterised by severe tissue injury and microvascular perfusion deficits. We hypothesised that leucopenia might provide significant protection against microvascular dysfunction and preserve tissue viability. Using our clinically relevant rat model of compartment syndrome, microvascular perfusion and tissue injury were directly visualised by intravital video microscopy in leucopenic animals. We found that while the tissue perfusion was similar in both groups (38.8% (standard error of the mean (sem) 7.1), 36.4% (sem 5.7), 32.0% (sem 1.7), and 30.5% (sem 5.35) continuously-perfused capillaries at 45, 90, 120 and 180 minutes compartment syndrome, respectively versus 39.2% (sem 8.6), 43.5% (sem 8.5), 36.6% (sem 1.4) and 50.8% (sem 4.8) at 45, 90, 120 and 180 minutes compartment syndrome, respectively in leucopenia), compartment syndrome-associated muscle injury was significantly decreased in leucopenic animals (7.0% (sem 2.0), 7.0%, (sem 1.0), 9.0% (sem 1.0) and 5.0% (sem 2.0) at 45, 90, 120 and 180 minutes of compartment syndrome, respectively in leucopenia group versus 18.0% (sem 4.0), 23.0% (sem 4.0), 32.0% (sem 7.0), and 20.0% (sem 5.0) at 45, 90, 120 and 180 minutes of compartment syndrome in control, p = 0.0005). This study demonstrates that the inflammatory process should be considered central to the understanding of the pathogenesis of cellular injury in compartment syndrome.

Cite this article: Bone Joint J 2015;97-B:539–43

Purpose: Severe compartment syndrome is associated with renal failure, end organ damage, and systemic inflammatory response syndrome (SIRS). Intravital videomicroscopy (IVVM) is a useful tool to study capillary perfusion and inflammation in end organs such as the liver and lungs. In this study, the systemic effect of hindlimb compartment syndrome was studied using hepatic IVVM. The purpose was to measure the effect of increased hindlimb intracompartmental pressure on hepatocyte viability, inflammation, and blood flow in a rodent model.

Method: Ten Wistar rats were randomised into control (C) and Compartment Syndrome (CS) groups. Animals were anaesthetized with 5 % isoflurane. Mean arterial pressure was monitored using a carotid artery catheter. Elevated intracompartmental pressure (EICP) was induced by saline infusion into the anterior compartment of the hind limb and maintained for 2 hours between 30–40mmHg in the CS group. Two hours following fasciotomy, the liver was analyzed using IVVM to quantify capillary perfusion as a measure of microvascular dysfunction. The numbers of adherent and rolling leukocytes in venules and sinusoids were quantified to measure the inflammatory response. Irreversible hepatocyte injury was measured using a fluorescent vital dye which labels the nuclei of severely injured cells.

Results: Hepatocellular injury was significantly higher in the CS group (325±103 PI labeled cells/10-1 mm2) compared to controls (30±12 PI labeled cells/10-1 mm2)(p=0.0087). The number of adherent venular white blood cells (WBC) was significantly higher for the CS group (5±2/hpf) than controls (0.2±0.2)(p=0.0099). Volumetric blood flow was not significantly different between CS and controls.

Conclusion: After only 2 hours of compartment syndrome in this animal model, the number of activated white blood cells increased 25-fold and liver cellular injury increased 10-fold compared to controls. Marked systemic inflammation and hepatocellular damage was detected in response to isolated limb compartment syndrome. Compartment syndrome is a low-flow ischemia/reperfusion injury with a profound inflammatory response. Further research into the severe end-organ damage associated with compartment syndrome is required.

Purpose: Compartment syndrome is a limb-threatening complication of skeletal trauma. Both ischemia and inflammation may be responsible for tissue necrosis in compartment syndrome (CS). In this study, normal rodents were compared with neutropenic animals to determine the importance of inflammation as a mechanism of cellular damage using techniques of intravital videomicroscopy (IVVM) and histochemical staining.

Method: Forty Wistar rats were randomised. Twenty animals served as a control (group C). Twenty rats were rendered neutropenic using cyclophosphamide (250mg/kg) (group N). Animals were anaesthetised with 5 % isoflurane. Elevated intracompartmental pressure was induced by saline infusion into the anterior hindlimb compartment and maintained at 30–40 mmHg for 0, 15, 45 or 90 minute time intervals. Following fasciotomy, the EDL muscle was analyzed using IVVM to quantify tissue injury, capillary perfusion, and inflammatory response.

Results: The proportion of injured cells decreased in group N compared to group C at all time intervals of EICP (p< 0.05). The proportion of injured cells in group N was 8 % after 0 minutes EICP, and 12, 15, and 10 % at 15, 45, and 90 min of EICP. In group C injured cells increased from 8 % to 20, 22, and 21 % at 15, 45, and 90 minutes EICP respectively. Groups N and C both demonstrated a time-dependent reduction in capillary perfusion. In group N continuously-perfused capillaries decreased from 79±4/mm with 0 min of EICP, to 48±11/mm (15min), 36±7/mm (45min), and 24±10/mm (90min) (p < 0.05). Overall, There was no difference between groups N and C with regards to perfusion (p> 0.05).

Conclusion: This study demonstrates the importance of inflammation as a cause of injury in compartment syndrome. There was a 50% decrease in injury in neutropenic animals compared to controls after 90 minutes of elevated intracompartmental pressure. Microvascular perfusion analysis demonstrated a time-dependent decrease in capillary perfusion in both neutropenic and control animals. Blocking of the inflammatory response via neutropenia was protective against tissue injury. These results provide evidence toward a potential therapeutic benefit for anti-inflammatory treatment of elevated intra-compartmental pressure.

Purpose: This study determined the relative role of inflammation and ischemia in cell damage using an animal model of compartment syndrome.

Method: Forty adult Wistar rats were studied according to a protocol approved by the animal care committee at our institution. Twenty rats were used as control animals, while an additional 20 rats were pretreated with cyclophosphamide to create a leucocyte-deplete state. Animals were anesthetized using 5% isoflurane. Mean arterial pressure was maintained at 80 mm Hg and core temperature was maintained at 36 degrees. Animals were then randomly assigned to one of 4 groups, in which hindlimb compartment pressure was maintained at 30 mm Hg for 0, 15, 45, or 90 minutes. Intravital microscopy was then utilized to study capillary perfusion, white blood cell activation, and cellular damage in the hindlimb EDL muscle.

Results: Inflammation: White blood cell activation was dampened in the neutropenic animals by approximately 85 % at all time periods. Capillary Perfusion: Perfusion was similar between the neutropenic and control animals. Both groups demonstrated a gradual decrease in the number of continuously perfused capillaries, from 80 % at 0 min of elevated intracompartmental pressure (EICP) to 30 % after 90 minutes of EICP. Cellular damage: Cellular damage, measured using a differential staining technique, decreased by 55 % in the neutropenic group after 90 minutes of EICP (p< 0.005).

Conclusion: Compartment syndrome is an important clinical problem resulting in severe muscle damage. In this study, inflammation was confirmed as an important causative element of cell damage. Based upon the results of this study, adjuvant treatment to fasciotomy designed to reduce inflammation and cellular damage may have important clinical benefit.

Elevated intracompartmental pressure (ICP) results in muscle damage. Previous studies identified severe inflammation associated with elevated ICP. This study was designed to determine whether indomethacin, a potent anti-inflammatory agent, reduces muscle damage secondary to elevated ICP. We hypothesised that administration of indomethacin reduces muscle damage from elevated ICP.

Sixteen adult Wistar rats were randomised to four groups. In group One (control), no intervention occurred. Group Two (indo) rats were administered indomethacin (12mg/kg) with no elevation of ICP. Group Three (CS) rats had elevated ICP (30–40mmHg X 45 minutes) using saline injection. Group Four rats (CS/indo) had elevated ICP and indomethacin administration. After forty-five minutes, hindlimb fasciotomy was performed. The extensor digitorum longus muscle was reflected onto an intravital microscope. Capillary perfusion was measured by comparing the number of continuously perfused capillaries to intermittent and non perfused capillaries. Inflammation was determined using the number of activated (rolling and adherent) white blood cells. Muscle cell damage was measured using differential fluorescent staining. Perfusion, inflammation, and muscle damage were compared in all four groups using a one-way ANOVA (p< 0.05).

Perfusion: Indomethacin treatment (CS/indo) increased the proportion of intermittently perfused capillaries (39.1 ± 2.2 vs 30.3 ± 2.7) and decreased nonperfused capillaries (38.4 ± 1.8 vs 50.1 ±2.5) compared to CS (p=0.0002). Control and indo groups demonstrated more continuously perfused capillaries compared to CS or CS/indo groups (p< 0.0001). Muscle damage: Indomethacin treatment of elevated ICP reduced the proportion of damaged cells from 0.20 ± 0.14 (CS) to 0.01 ± 0.0.005 (CS/indo, p< 0.0001). There were no differences between CS/indo, control, or indo groups. Inflammation: CS and CS/indo groups demonstrated greater inflammatory activation compared to control and indo groups (p< 0.001). There were no differences in inflammatory activation between CS and CS/indo (p> 0.05).

Treatment of elevated ICP with indomethacin improved microvascular perfusion and reduced cell damage. The protective mechanism of indomethacin is unknown, but may be related to an anti-oxidative and vasodilatory effect. Treatment of elevated intracompartmental pressure with indomethacin dramatically reduces muscle damage and may have important future clinical benefit.

Elevated intracompartmental pressure (ICP) results in tissue damage due to impaired microcirculatory function. The nature of microcirculatory impairment in elevated ICP is not well understood. This study was designed to measure the effects of increased ICP on skeletal muscle microcirculation, inflammation and cell viability using intravital videomicroscopy.

Twenty adult male Wistar rats were randomised to four groups: the control group (control) had no intervention; while three experimental groups had elevated ICP maintained for fifteen (15m), 45 (45m), or ninety (90m) minutes. Compartment pressure was continuously monitored and controlled between 30¡V40mmHg in the posterior hindlimb using saline infusion into the anterior hindlimb. Mean arterial pressure was maintained between 80 and 120mmHg. Fasciotomy was then performed and the Extensor Digitorum Longus muscle studied using intravital videomicroscopy. Perfusion was measured by comparing the numbers of continuous, intermittent, and nonperfused capillaries. Inflammation was measured by counting the number of activated (rolling and adherent) leukocytes in post-capillary venules. Muscle cellular Injury was measured using fluorescent vital staining of injured cell nuclei.

Perfusion: The number of continuously perfused capillaries decreased from 77 ± 3/mm (control) to 46 ± 10/mm (15m),40±10/mm(45m)and27±8/mm(90m)(p< 0.05). Non-perfused capillaries increased from 13 ± 1 (control) to 16 ± 4 (15m), 30 ± 7 (45m), and 39 ± 5 (90m) (p< 0.05). Inflammation: Activated leukocytes increased from 3.6 ± 0.7/(100ƒÝ)2 (control) to 5.9 ± 1.3 (15m), 8.6 ± 1.8 (45m), and 10.9 ± 3.0/(100ƒÝ)2 (90m) (p< 0.01). Injury: The proportion of injured cells increased from 5 ± 2 % in the control group to 12 ± 3 (15m), 16 ± 7 (45m) and 20 ± 3 % (90m) (p< 0.05).

As little as fifteen minutes of 30mmHg ICP caused irreversible muscle damage and microvascular dysfunction. With increased duration, further decreases in capillary perfusion and increases in injury are noted. A severe inflammatory response accompanies elevated ICP. The role of inflammation in compartment syndrome is unknown, but may contribute to cell injury and reduced capillary perfusion.