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. Using a rat model of compartment syndrome, its systemic effects
on the viability of hepatocytes and on inflammation and circulation
were directly visualised using intravital video microscopy.Aims
Methods
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 ( Cite this article:
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.