Abstract
Resuscitation induced ischemia/reperfusion predisposes trauma patients to systemic inflammation and organ dysfunction. We investigated the effect of remote ischemic conditioning (RIC), a treatment shown to prevent ischemia/reperfusion injury in experimental models of hemorrhagic shock/resuscitation, on the systemic immune-inflammatory profile in trauma patients in a randomized trial. We conducted a prospective, single-centre, double-blind, randomized, controlled trial involving trauma patients sustaining blunt or penetrating trauma in hemorrhagic shock admitted to a Level 1 trauma centre. Patients were randomized to receive RIC (four cycles of 5-min pressure cuff inflation at 250 mmHg and deflation on the thigh) or a Sham intervention. The primary outcomes were neutrophil oxidative burst activity, cellular adhesion molecule expression, and plasma levels of myeloperoxidase, cytokines and chemokines in peripheral blood samples, drawn at admission (pre-intervention), 1 h, 3 h, and 24 h post-admission. Secondary outcomes included ventilator, ICU and hospital free days, incidence of nosocomial infections, 24 h and 28 day mortality. 50 eligible patients were randomized; of which 21 in the Sham group and 18 in the RIC group were included in the full analysis. No treatment effect was observed between Sham and RIC groups for neutrophil oxidative burst activity, adhesion molecule expression, and plasma levels of myeloperoxidase and cytokines. RIC prevented significant increases in Th2 chemokines TARC/CCL17 (P < 0.01) and MDC/CCL22 (P < 0.05) at 24 h post-intervention in comparison to the Sham group. Secondary clinical outcomes were not different between groups. No adverse events in relation to the RIC intervention were observed. Administration of RIC was safe and did not adversely affect clinical outcomes. While trauma itself modified several immunoregulatory markers, RIC failed to alter expression of the majority of markers. However, RIC may influence Th2 chemokine expression in the post resuscitation period. Further investigation into the immunomodulatory effects of RIC in traumatic injuries and their impact on clinical outcomes is warranted.
ClinicalTrials.gov number: NCT02071290.
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Introduction
Traumatic injuries continue to be a leading cause of mortality worldwide1 despite significant advances in the comprehensive treatment of the trauma patient. Organ dysfunction observed in severely injured resuscitated patients, is, in part, attributed to the development of systemic immune dysfunction2,3. The pathophysiological process of ischemia/reperfusion occurring in patients resuscitated from hemorrhagic shock initiates a cascade of cellular events leading to an altered immune status, and includes generation of oxidative stress, release of inflammatory cytokines, and the priming of immune cells2,4,5. The attendant phenotypic switch from Th1 to Th2 adaptive immunity post resuscitation is associated with immunosuppression6. Together these events predispose trauma patients to the systemic inflammatory response syndrome, acute respiratory distress syndrome, infections, and multiple organ dysfunction7.
An intervention that has been shown to lessen the magnitude of ischemia/reperfusion injury is called Remote Ischemic Conditioning (RIC)8. RIC is a non-invasive therapeutic procedure consisting of repetitive applications of brief ischemia/reperfusion to a distal limb by inflating and deflating a pressure cuff. In experimental studies, antecedent administration of RIC ameliorates distant organ ischemia/reperfusion injury. RIC has also been shown to exert anti-inflammatory effects when applied in healthy volunteers9,10. These findings have been translated to clinical trials to show a beneficial effect of RIC in renal11 and cardiac12 protection. There has been considerable study of the mechanisms underlying the salutary effects of RIC on distant organ injury. Both humoral and neuronal pathways have been invoked, often with both being involved and frequently interacting, in mediating the transfer of the upstream signal i.e. RIC to downstream organ protection13,14. Further, both may be involved in the downstream effect leading to organ protection. It has also been reported that the elaboration of reactive oxygen species by the preconditioning intervention might exert protection through activation of redox-sensitive events15.
In the trauma setting, Joseph et al. demonstrated that RIC applied in patients following traumatic brain injury exerted neuroprotective effects, as determined by a reduction of neuronal biomarkers of acute brain injury in the blood16. In animal models of hemorrhagic shock/resuscitation, we and others have shown the protective effect of RIC in preventing organ injury in the liver17, lung17,18, brain19 and heart20. However, its ability to more broadly modulate immune function in trauma populations sustaining hemorrhagic shock, has not been evaluated. Whether RIC applied post-injury in trauma patients can initiate its upstream signaling and downstream protective effect, in which hemorrhage has led to hemodynamic instability, inflammatory responses, immune cell alterations, platelet dysfunction, and coagulopathy, remains to be determined.
We hypothesized that RIC may suppress the inflammatory response associated with traumatic resuscitated hemorrhagic shock. The major objective of this clinical trial is to investigate the potential immunomodulatory effects of posttraumatic application of RIC in trauma patients sustaining hemorrhagic shock by evaluating markers of neutrophil activation and systemic inflammation during the acute phase of injury.
Methods
Patient population and study design
A prospective, single-centre, randomized, controlled double-blind clinical trial was conducted at St. Michael’s Hospital, Unity Health Toronto, a Level 1 provincial trauma centre, to investigate the immunomodulatory effects of Remote Ischemic Conditioning in trauma patients (age > 16) sustaining blunt or penetrating injuries and in hemorrhagic shock. The trial is registered on ClinicalTrials.gov (Identifier: NCT02071290) on 25/02/2014. Hemorrhagic shock was defined as one or more recorded episode of systolic blood pressure under 90 mmHg at any time prior to enrolment with an identified source of blood-loss. The RIC procedure was to be completed within 4 h of injury to be eligible. Major exclusions included patients who were on anticoagulant medication, pregnancy, recorded systolic blood pressure of above 200 mmHg, burns, absence of vitals, or ongoing cardiopulmonary resuscitation. Patients were enrolled by research coordinator through deferred consent as permitted by The Tri-Council Policy Statement on the Ethical Conduct of Research with Humans (TCPS2) and informed consent was obtained from all participants by the substitute decision maker within 24 h of enrolment. After randomization, blood samples were collected into citrate, EDTA, and heparin vacutainers at Admission (prior to initiation of Sham or RIC intervention), and at 1, 3, and 24 h after admission. These timepoints were chosen to reflect the biphasic cytoprotection afforded by RIC21; i.e. the early cytoprotection that lasts up to ~ 3 h after RIC (first window of protection) and the late cytoprotection that emerges ~ 24 h after RIC (second window of protection). Fresh heparinized whole blood samples for flow cytometric analysis were stained within 1 h of collection. Admission data including patient demographics, diagnostic laboratory values, and outcomes were collected.
As healthy controls, an additional 10 volunteers were enrolled and subjected to identical blinding, exclusion criteria, and randomization procedure as trauma patients to receive either Sham (n = 5) or RIC intervention (n = 5). The combined Admission values from the 10 volunteers served as Healthy Control comparisons to trauma patients.
The study was approved by the Research Ethics Board at St. Michael’s Hospital, Unity Health Toronto (14-047). All methods and procedures were performed in accordance with guidelines and regulations of The Tri-Council Policy Statement on the Ethical Conduct of Research with Humans (TCPS2).
Randomization and blinding
Patients were randomized in a 1:1 ratio to receive either a sham intervention or RIC intervention by a sealed envelope containing the treatment allocation. The randomization schedule was generated in R using random permuted blocks of sizes 2 and 4 by a statistician who was not involved in the trial. The study investigators and research staff who performed laboratory tests were blinded to the treatment allocation.
Interventions
RIC was performed using a pneumatic tourniquet (Zimmer A.T.S. 3000, Zimmer, Mississauga, ON, Canada) by inflation of a sterile pressure cuff (Vari Fit Contour Tourniquet Cuff, Delfi Medical Innovations, Vancouver, BC, Canada) on the thigh at 250 mmHg for 5 min followed by deflation at 0 mmHg for 5 min and repeated for four cycles. The Sham intervention consisted of application of the thigh cuff with the inflation period set to 0 mmHg. Patients were observed for any local events related to inflation of the cuff.
Outcomes
The primary outcomes were neutrophil oxidative burst activity, neutrophil cell surface adhesion molecule expression and plasma levels of cytokines and chemokines in blood samples taken at admission (pre-intervention), and one, three, and 24 h post admission. Secondary clinical outcomes assessed at 28 days included ventilator free days, ICU free days, hospital free days, nosocomial infections, and 24 h and 28 day mortality.
Feasibility outcomes
Outcomes for the feasibility of RIC include the ability to enrol eligible patients in the trauma bay, application and completion of RIC, interruption of RIC cycles, total duration of RIC, and duration from time of injury to application of RIC.
Neutrophil oxidative burst activity
The intracellular oxidative burst capacity of neutrophils was measured using commercially available flow cytometric kit (PHAGOBURST; Glycotope Biotechnology, Heidelberg, Germany). Heparinized whole blood (100 µl) was incubated with either wash buffer (unstimulated control), stimulated with PMA (1.35 µM) or fMLP (0.83 µM) for 10 min at 37 °C followed by incubation with DHR-123 substrate for 10 min at 37 °C. Erythrocytes were lysed with the addition of Lysing Solution (Glycotope Biotechnology). Cells were centrifuged at 250×g for 5 min, washed once, and stained with CD14-Alexa Fluor 647 (clone MφP9; BD Biosciences) and CD16-eFluor 450 (clone CB16; Affymetrix) antibodies at 4 °C for 30 min. Stained cell suspensions were acquired using LSRFORTESSA X-20 flow cytometer (BD Biosciences) within 30 min of staining on 10,000 CD16+CD14− neutrophils. Unstained controls in separate tubes were used to control for autofluorescence. Data were analyzed by FACSDIVA (BD Biosciences) and the Median Fluorescence Intensity (MFI) for Rho-123 was recorded.
Neutrophil cell-surface adhesion molecule
Neutrophil cell surface adhesion molecules were assessed with antibodies staining for CD11b-PE (clone CBRM1/5; Affymetrix) and CD62L-FITC (clone DREG-56; BD Biosciences). Antibodies staining for CD14-Alexa Fluor 647 (clone MφP9; BD Biosciences) and CD16-eFluor 450 (clone CB16; Affymetrix) were used to facilitate separation of monocyte and neutrophil populations respectively. Heparinized whole blood (100 µl) was incubated with either wash buffer (unstimulated control), PMA (1.35 µM), or fMLP (0.83 µM) for 10 min at 37 °C followed by staining with antibodies for 20 min at room temperature in the dark. Erythrocytes were lysed with the addition FACS Lysing Solution (BD Biosciences). Cells were spun at 250×g for 5 min, washed once, and resuspended in 1% BSA-PBS. Stained cell suspensions were acquired using LSRFORTESSA X-20 flow cytometer (BD Biosciences) on 10,000 CD16+CD14− neutrophils. Unstained controls in separate tubes were used to control for autofluorescence. Data were analyzed by FACSDIVA (BD Biosciences) and the Median Fluorescence Intensity (MFI) for CD11b and CD62L were measured.
Plasma cytokine, chemokine, and myeloperoxidase
Whole blood collected in EDTA vacutainers were centrifuged at 2500g for 15 min to acquire plasma and aliquots were frozen in − 80 °C until analysis. Plasma levels of a panel of 30 cytokines and chemokines were measured using an electrochemiluminescence-based multiplex sandwich immunoassay (V-PLEX Human Cytokine 30-Plex Kit, Meso Scale Diagnostics). Myeloperoxidase (MPO) was measured using Human Myeloperoxidase Kit (Meso Scale Diagnostics). Analytes were analyzed on a Sector Imager 6000 (Meso Scale Diagnostics) according to manufacturer’s instructions. The cytokine and chemokines assayed from this kit include Eotaxin, Eotaxin-3, granulocyte–macrophage colony stimulating factor (GM-CSF), Interferon γ (IFN-γ), interleukin (IL)-10, IL-12/IL-23p40, IL-12p70, IL-13, IL-15, IL-16, IL-17A, IL-1α, IL-1β, IL-2, IL-4, IL-5, IL-6, IL-7, IL-8, IL-8 (HA), Inducible protein-10 (IP-10), monocyte chemoattractant protein-1 (MCP-1), MCP-4, Macrophage-derived chemokine (MDC/CCL22), Macrophage inflammatory protein-1α (MIP-1α), MIP-1β, Thymus and Activation Regulated chemokine (TARC/CCL17), tumour necrosis factor α (TNF-α), TNF-β, Vascular endothelial growth factor a (VEGF-a). Samples were measured in duplicate and results were used for statistical analysis only if plasma levels fell within the lower and upper limits of detection, were detectable in ≥ 80% of analyzed samples, and had a percentage coefficient of variance < 25% between replicates. As a result, IL-1α, IL-1β, IL-2, IL-4, IL-8 (HA), IL-12p70, IL-13, MIP-1α, GM-CSF, Eotaxin-3, and TNF-β were excluded from analysis.
Statistical analysis
Sample size calculation was based on the variance from previous clinical trial in a similar cohort of trauma patients (SD of 27.2 for CD11b and SD of 20.1 for CD62L). A sample size of 20 for each group gives 80% power to detect a difference of 24.7 for CD11b or 18.2 for CD62L. Such differences represent clinically important differences in neutrophil activation. Data analysis was performed using SPSS version 23 (SPSS, Chicago, Illinois). Patient admission characteristics and outcomes were compared by Mann–Whitney U or χ2 test where appropriate. A linear mixed model was used for repeated measures analysis. Post hoc comparisons were performed on the Estimated Marginal Means adjusting for the trauma patients’ admission value, Injury Severity Score, base deficit, age, and time to intervention from injury. Post hoc comparisons between healthy controls were adjusted for Admission values. Multiple comparisons were subjected to Bonferroni correction. Comparisons between trauma patients and healthy controls were performed by one-way analysis of variance followed by Dunnett’s post hoc test. Data for linear mixed model and analysis of variance were tested for normality using Shapiro–Wilk test and non-parametric data were log transformed prior to analysis. Continuous data are expressed as median (interquartile range). A P value of < 0.05 was considered statistically significant.
Results
A total of 1447 trauma patients admitted to St. Michael’s Hospital were screened for eligibility between May 2015 to October 2016, of whom 72 patients met enrolment criteria (Fig. 1). Of the 72 eligible patients, 50 patients were enrolled and randomized between Sham (n = 25) and RIC interventions (n = 25). 11 of the 50 enrolled patients became ineligible after randomization. A total of 39 patients were included in the final analysis: 21 in the Sham group and 18 in the RIC group. Patient pre-hospital and admission clinical characteristics were not significantly different between Sham and RIC groups (Table 1).
Clinical outcomes including ventilator free days, ICU free days, hospital free days, nosocomial infections, and mortality were not significantly different between Sham and RIC groups (Table 2). No adverse events were observed related to the administration of the RIC intervention.
Feasibility of RIC
Of the 25 enrolled patients in the Sham arm, the intervention was completed in 23 patients: 2 of the patients did not have the intervention initiate due to death of one patient after enrolment and another patient was not able to initiate the intervention within the inclusion period time frame. Of the 25 enrolled patients in the RIC arm, 20 patients completed the RIC intervention. The intervention was not initiated in 3 patients due to the inability to draw admission blood from one patient, one patient opted out of the study, and one patient was not able to initiate RIC within the inclusion period time frame. Two of RIC patients had the intervention started but prematurely terminated before all the cycles were completed due to the necessity to perform vascular surgery on the leg which RIC was performed and one patient had the intervention stopped during the first ischemic cycle due to discomfort. In addition, 4 patients from the Sham arm and 5 patients from the RIC arm had the RIC cycles interrupted due to transfer of the patients out to other departments including the Intensive Care Unit, CT Scan, or Operating Room where the interventions were resumed following transfer. The mean time for the completion of the intervention for patients who had the intervention interrupted was not significantly different between the Sham intervention (68 ± 22 min) and the RIC intervention (68 ± 21 min, P = 0.99).
The mean duration from injury to application of the Sham intervention (114 ± 53 min) was not different in comparison to the RIC intervention (130 ± 50 min, P = 0.31). The mean duration from the time of injury to completion of the intervention was also not significantly different between Sham (154 ± 56 min) and RIC (181 ± 46 min, P = 0.09) patients. Both arms had two patients in which completion of the intervention exceeded the 4 h inclusion period time frame. Significant positive correlations were observed between APACHE II score (Supplementary Fig. 1A) and the Injury Severity Score (Supplementary Fig. 1B) to the duration of time from injury to initiation of the intervention, suggesting the complexity of injuries and the patients’ pathological conditions contribute to the variability and delay in the application of RIC.
The median duration for transport time from the arrival to scene of injury to admission was 25 min (IQR: 15, 34) by ambulance and 70 min (IQR: 51, 85) by helicopter. Those patients who had prolonged transport time were due to transfers from other hospitals. These data suggest there is potentially sufficient time for pre-hospital application of RIC during EMS transport.
Neutrophil oxidative burst, adhesion molecules, and MPO (Figs. 2 and 3)
Unstimulated neutrophil ROS production was lower at Admission in the Sham (P < 0.05) and RIC groups (P = 0.079) and remained significantly lower at 1 and 3 h compared to healthy controls. By 24 h, ROS did not differ from healthy controls (Fig. 2A). In RIC treated patients, unstimulated ROS production decreased significantly at 3 h post intervention in comparison to Admission values. PMA-stimulated neutrophil ROS from trauma patients exposed to Sham intervention was significantly higher than healthy controls on admission and gradually fell, becoming no different from healthy controls by 3 h. ROS elaborated by PMA stimulated neutrophils from RIC-treated patients similarly fell over the first 24 h and at no time point did this significantly differ from Sham treated trauma patients. (Fig. 2B). Patients receiving the RIC intervention had significantly lower PMA stimulated ROS production at 24 h post intervention in comparison to healthy controls, a finding that was also seen in the Sham group, although not statistically significant (P = 0.408). Neutrophil ROS in response to fMLP was significantly lower at all time points in comparison to healthy controls for both Sham and RIC groups (Fig. 2C), but did not differ from each other.
The cell surface expression of neutrophil CD11b was not significantly different between Sham or RIC-treated trauma patients and healthy controls under unstimulated, PMA, or fMLP conditions (Fig. 3A–C, respectively) at any time point. PMA stimulated CD11b expression was higher at 3 and 24 h post intervention for the RIC group in comparison to Admission values (Fig. 3B), a finding not seen in Sham patients. fMLP stimulated CD11b expression was transiently decreased in the Sham group, at 1 h post intervention in comparison to Admission values (Fig. 3C).
Cell surface CD62L expression was increased in trauma neutrophils at Admission in both Sham and RIC groups, compared to healthy controls and gradually returned towards levels in healthy control by 24 h post intervention (Fig. 3D). Stimulation with PMA and fMLP reduced surface CD62L (Fig. 3E,F). No significant differences between the Sham and RIC groups were detected in unstimulated CD62L expression or after PMA or FMLP stimulation.
Sham-treated trauma patients had a significant increase in MPO (Fig. 3G) at 1 and 3 h after admission compared to healthy controls, a finding not observed at comparable time points in RIC-treated patients. By 24 h post admission, plasma MPO was elevated in both sham and RIC patients compared to healthy controls. No differences were observed between Sham and RIC-treated patients at any of the time point studied.
Effect of RIC on plasma cytokines and chemokines
Increased plasma levels of IL-6 were observed in trauma patients compared to healthy controls upon admission and progressively increased over the 24 h study period in both Sham and RIC patients (Fig. 4A). Levels of TNF-α did not differ between trauma patients and healthy controls, either at the time of admission or over the 24 h course of study (Fig. 4B). IL-10 was elevated in both Sham and RIC upon admission in trauma patients compared to healthy controls and did not change over the 24 h post-intervention period (Fig. 4C). RIC did not significantly influence the plasma levels of IL-6, TNF-α, and IL-10 in comparison to Sham patients at any of the time points studied.
Cytokines including IL-15, IL-16, and IL-17A (Supplement Fig. 2A–C) were increased following traumatic injuries in comparison to healthy controls but did not differ between Sham and RIC treated patients. Levels of IL-12p40 (Supplement Fig. 2D) were decreased at 24 h post intervention in the Sham group in comparison to healthy controls. Levels of IFN-γ (Supplement Fig. 2E), IL-5 (Supplement Fig. 2F), IL-7 (Supplement Fig. 2G) were not different between trauma patients and healthy controls. VEGF (Supplement Fig. 2H) was significantly increased at 24 h in Sham patients in comparison to Admission values and healthy controls, but this increase was not observed in RIC patients. Application of RIC did not alter the plasma levels of molecules associated with innate or adaptive immunity compared to Sham treatment.
Traumatic injuries induced changes in a number of chemokines (Fig. 5). MDC/CCL22 (Fig. 5A) and TARC/CCL17 (Fig. 5B), both of which are chemokines for Th2 signaling, were significantly elevated at 24 h post intervention in Sham patients compared to admission. This rise was not observed in patients who received RIC and at the 24 h timepoint, there was a significant difference between sham and RIC treated trauma patients (MDC: P < 0.05; Cohen’s d = 0.54), TARC: P < 0.01; Cohen’s d = 0.58). Plasma levels of MIP-1β (Fig. 5C), MCP-1 (Fig. 5D), IL-8 (Fig. 5E), and Eotaxin (Fig. 5F) were significantly increased after trauma in comparison to healthy controls but there was no difference between Sham and RIC groups. Levels of IP-10 (Supplement Fig. 3A) and MCP-4 (Supplement Fig. 3B) were not significantly different between trauma patients and healthy controls.
Effect of RIC in neutrophil oxidative burst activity and adhesion in healthy controls
As a positive control for the effectiveness of the RIC procedure used in these studies, we performed this protocol in healthy controls and measured its effect on neutrophil ROS and adhesion molecules. Application of RIC in healthy controls significantly decreased unstimulated neutrophil ROS production in comparison to Sham healthy controls at 1, 3, and 24 h post intervention (Table 3). PMA stimulated ROS production was also significantly lower in RIC treated healthy controls at 24 h post intervention (Table 3). ROS production after stimulation with fMLP was not significantly different between Sham and RIC healthy controls.
RIC significantly decreased neutrophil expression of CD11b at 3 and 24 h post intervention in comparison to Sham healthy controls (Table 3). Expression of CD11b after stimulation with PMA or fMLP was not significantly different between Sham and RIC treated healthy controls (Table 3). RIC did not significantly influence expression of CD62L in neutrophils under unstimulated, PMA, or fMLP stimulated conditions in healthy controls (Table 3).
Plasma cytokines, chemokines, and MPO in healthy controls
Plasma levels of cytokines, chemokines, and MPO were not significantly different between healthy controls receiving the Sham and RIC intervention in each of the time points measured after the intervention (Supplementary Table 1).
Discussion
Dysregulated immuno-inflammatory responses may contribute to adverse outcomes following traumatic hemorrhagic shock despite successful resuscitation protocols3. The present clinical trial is the first study to investigate the immunomodulatory effects of remote ischemic conditioning in trauma patients sustaining hemorrhagic shock. Based on the salutary effects of RIC in experimental models of ischemia/reperfusion injury and hemorrhagic shock/resuscitation, we hypothesized that RIC exerts anti-inflammatory effects in hemorrhagic shock patients during the acute phase of injury. We demonstrated that application of RIC in hemorrhagic shock patients upon arrival in the Emergency Room at our institution was feasible, safe, tolerable, and not associated with adverse outcomes. The RIC protocol employed in this study, namely four cycles of inflation/deflation on the thigh, inhibited baseline and stimulated ROS production in neutrophils when applied to healthy controls. However, in our cohort of trauma patients, we did not observe significant changes in neutrophil activation, plasma pro-inflammatory markers, and clinical outcomes in patients treated with RIC in comparison to the Sham treatment. Still, we observed that RIC prevented a significant increase in Th2 cytokines in Sham-treated trauma patients—an effect that may potentially prevent Th2 induced immunosuppression.
Ischemia/reperfusion injury is a pathological process caused by tissue ischemia followed by restoration of perfusion, which together initiate a cascade of cellular events culminating in the tissue injury due to the generation of oxidative stress, initiation of the cell death pathways and generation of pro-inflammatory molecules22. In the context of trauma-induced hemorrhagic shock, post-trauma resuscitation induces ischemia/reperfusion in tissues and contributes to systemic inflammation and organ dysfunction. The extravasation and activation of neutrophils play a key role in the pathogenesis of organ injury through degranulation and the release of injurious enzymes and ROS. Consistent with prior reports, we observed priming of neutrophils, increased surface adhesion molecule expression, and degranulation of MPO during the early injury period concomitant with an early rise in the immunomodulatory cytokine IL-6 and chemokine IL-8 in our cohort of trauma patients. We asked the question whether RIC application in trauma-induced hemorrhagic shock patients might alter this pro-inflammatory profile, along with neutrophil ROS production and CD11b expression, both unstimulated and in response to PMA and fMLP. In the current study, the application of RIC following traumatic injury did not exert effects on these parameters and specifically, at no time point did neutrophil ROS production and CD11b expression differ, whether unstimulated or in response to PMA, between RIC and sham groups. We also observed that there was lower unstimulated and fMLP stimulated ROS production in both Sham and RIC treated patients compared to healthy controls, and a gradual decline in PMA stimulated ROS production, which normalized by 24 h post intervention for both groups. This may have been due to the elaboration of IL-10. This anti-inflammatory cytokine, known to exert inhibitory effects on neutrophil ROS production and phagocytic activity23, was elevated in both sham and RIC trauma patients throughout the study compared to healthy controls.
In addition to degranulation, activated neutrophils have also been shown to secrete VEGF24. Patients in the Sham group exhibited significant increases in plasma VEGF levels at 24 h post intervention, but this increase was not observed in the RIC group. The role of VEGF post injury remains controversial due to its dual role in inducing endothelial permeability and angiogenesis25. However, VEGF is associated with increased vascular permeability in patients with acute respiratory distress syndrome.
In our investigation of a panel of cytokines/chemokines, we observed that RIC prevented the significant increases in the cytokines MDC/CCL22 and TARC/CCL17 at 24 h post intervention. Both MDC and TARC are specific ligands for C–C chemokine receptor type 4, a receptor expressed on myeloid cells and lymphocytes but predominately on Th2 cells26. In addition to activating the Th2 response, TARC inhibits generation of classically activated macrophages resulting in impaired innate immunity27. Our findings suggest a potentially novel role for RIC in the modulation of T cell mediated innate immunity, as post traumatic shift from Th1 towards an anti-inflammatory Th2 phenotype contributes to susceptibility to nosocomial infections6 and development of sepsis and poorer outcomes. This suggestion is further supported by recent animal models, where RIC elicited increased T cell anti-inflammatory cytokine production with an attendant shift from Th17 cells towards Treg cells28. Importantly, Richter et al. revealed a role for MDC in mediating lung inflammation in a murine model of hemorrhagic shock/resuscitation as administration of neutralizing antibodies against MDC significantly reduces pulmonary levels of the chemotactic cytokines KC, MIP-2, and MIP-1α and extravasation of inflammatory cells29. Another potential beneficial effect of inhibiting MDC and TARC during the late resuscitation period is that MDC and TARC stimulate platelet aggregation30, which may induce thrombosis post trauma. The upregulation of antioxidants may play a role in the down regulation of MDC and TARC. Jeong and colleagues demonstrated that induction of HO-1 prevents IFN-γ and TNF-α-induced production of TARC and MDC through suppression of NF-κB in human keratinocytes31. Notably, induction of the antioxidant heme oxygenase-1 by RIC mediates lung protection in a rodent model of hemorrhagic shock/resuscitation18. We have also recently shown in a murine model that Nrf2, the upstream transcription factor for antioxidant response, mediated hepatoprotection by RIC after hemorrhagic shock/resuscitation32. In this trial, we did not observe any differences in the incidence of nosocomial infections or clinical outcomes between the Sham and RIC group, although our trial is not powered to detect such differences. Further studies are warranted to characterize T-cell phenotype and the innate immunity after RIC treatment post trauma.
Several studies in humans have sought to determine the potential mediators of RIC and have measured a number of humoral and immunomodulatory molecules, including plasma levels of cytokines, hormones, and factors33,34,35,36. These findings are summarized in Supplementary Table 2. Notably, Gedik et al. identified increased plasma IL-1α as a potential cardioprotective factor of RIC that protects the myocardium during ischemic cardioplegic arrest34. Although IL-1α was measured in our study, analysis was excluded as < 80% of samples had detectable levels. The study by Dewitte et al. found RIC increased plasma levels of antioxidant superoxide dismutase in a model of vascular injury in healthy volunteers36. Our present study did not measure superoxide dismutase, but this finding supports our prior animal study that determined the role of antioxidants in RIC-mediated protection32.
Limitations
Despite a wealth of preclinical evidence pointing to the therapeutic effect of RIC in ischemia/reperfusion injury, translation to the clinical setting has been difficult37. Large prospective multicentre clinical trials have failed to demonstrate the efficacy of RIC in improving outcomes in the settings of cardiovascular surgery38 and acute myocardial infarction39. Several factors have been postulated that may negate the effects of RIC. These include surgical anesthesia, co-morbidities, age, as well as timing, route, and dose of RIC administration10,40. Many of these factors were pertinent in our trial and may have contributed to the neutral results of our study.
The nature of traumatic injuries and patient triage/transfer to our trauma centre affected our ability to precisely control the timing of initial RIC application across all patients as it relates to time after injury. Patients from our study had a median time of application at 2 h after injury, likely representing the post-resuscitative phase of injury. While there is no definitive clinical evidence to suggest the delayed application of RIC influences its protective effect, animal studies from our lab have shown that delaying RIC after shock/resuscitation in the early reperfusion period can diminish its protective effect17. Therefore, future trials on RIC might focus on pre-hospital application of RIC or try to standardize the intervention by applying RIC as soon as patients arrive to the trauma bay. One interesting patient population might be soldiers at risk of traumatic injuries who may have RIC applied prophylactically (preconditioning) during pre-deployment41. Any of these strategies might serve to maximize RIC’s protective effect.
The heterogeneity in trauma patients results in a number of clinical characteristics that significantly differ between each patient. These include the number of blood products transfused, surgical procedures, and anesthesia regimens. Each of these variables can contribute to a different immunological response6,42. Anesthesia is a major factor that may confound with the effects of RIC. For example, propofol has been shown to inhibit the cardioprotective effect of RIC in cardiac surgery43, whereas volatile anesthesia and opioids mimic the protective effects of RIC. The use of anesthesia was largely variable across our patient population and presents as a limitation in our study.
Previous studies in healthy volunteers that demonstrated the anti-inflammatory effect of RIC on leukocyte gene expression utilized the arm to conduct RIC9. Our current study utilized the thigh to induce RIC to permit the clinical resuscitation protocols performed on trauma patients. Controversy exists regarding the effectiveness of arm RIC versus leg RIC although a recent study by Dezfulian et al. demonstrated no significant differences in the liberation of nitrite—an effector circulating molecule of RIC, and the downstream cytoprotection induced by either method44. We showed in our healthy controls that thigh RIC induced down regulation of neutrophil oxidative burst and adhesion molecule expression, indicating the RIC stimulus applied on the leg reproduced the anti-inflammatory effect as forearm RIC. One potential explanation for reduced effect of RIC in trauma patients is that endothelial dysfunction, which develops in the early injury period45, has been shown to inhibit the generation of nitrite following reactive hyperemia46 and may therefore contribute to reduced generation of cytoprotective molecules by RIC. The significant reduction in peripheral blood flow to the limbs during hemorrhagic shock may also impair the initiation of signaling in the periphery by RIC. It is also unknown which dose (cycles) of RIC evokes optimal protective effects in humans as no dose response trial has been conducted10.
Activation of the vago-splenic axis has been shown by Lieder et al. to be causally involved in cardioprotection by RIC, implicating the spleen as a critical relay organ for its protective signaling47. In addition to severely impaired perfusion of the spleen during hemorrhage, splenic immune response and cellular immunity are further suppressed48, which together may potentially impair RIC’s protective signaling in trauma patients. To determine if arterial blood pressure during onset of RIC influences its effect, we performed post hoc analysis on subgroups of patients using surrogate markers of severe hemorrhagic shock (transfusion of blood products or no transfusion; injury severity score below or over 15; and admission systolic blood pressure below or over 90 mmHg) and found that these subgroups did not impact RIC on the biomarkers measured in this study. Traumatic injuries also impair platelet function, as platelets become inert to ex vivo stimulation, in a condition known as platelet exhaustion49. Lieder et al. recently demonstrated that platelets play a causal role in RIC signaling50. Thus, platelet dysfunction as a consequence of trauma may contribute to undermine RIC’s signaling.
In summary, our study was the first trial to investigate the immunomodulatory effect of RIC in humans sustaining traumatic hemorrhagic shock. We demonstrate that post-trauma application of RIC in hemorrhagic shock patients is safe, feasible and not associated with adverse outcomes. Although RIC induced anti-inflammatory effects in neutrophils taken from healthy volunteers, this effect was not recapitulated in trauma patients, which may in part be due to confounding factors, including the timing of the intervention. However, RIC prevented the increase in Th2 cytokines that are associated with immunosuppression. Results from our preliminary study in trauma patients in hemorrhagic shock suggest further investigation into the possible immunomodulatory mechanisms of RIC on the post-trauma immuno-inflammatory response and its impact on clinical parameters.
Data availability
All data generated or analyzed during this study are included in this published article [and its supplementary information files].
References
GBD-CoD-Collaborators. Global, regional, and national age-sex specific mortality for 264 causes of death, 1980–2016: A systematic analysis for the Global Burden of Disease Study 2016. Lancet 390(10100), 1151–1210 (2017).
Lord, J. M. et al. The systemic immune response to trauma: An overview of pathophysiology and treatment. Lancet 384(9952), 1455–1465 (2014).
de Jager, P., Smith, O., Pool, R., Bolon, S. & Richards, G. A. Review of the pathophysiology and prognostic biomarkers of immune dysregulation after severe injury. J. Trauma Acute Care Surg. 90(2), e21–e30 (2021).
Tsukamoto, T., Chanthaphavong, R. S. & Pape, H. C. Current theories on the pathophysiology of multiple organ failure after trauma. Injury 41(1), 21–26 (2010).
Partrick, D. A., Moore, F. A., Moore, E. E., Barnett, C. C. Jr. & Silliman, C. C. Neutrophil priming and activation in the pathogenesis of postinjury multiple organ failure. New Horiz. 4(2), 194–210 (1996).
Torrance, H. D. et al. Association between gene expression biomarkers of immunosuppression and blood transfusion in severely injured polytrauma patients. Ann. Surg. 261(4), 751–759 (2015).
Marshall, J. C. & Deutschman, C. S. The multiple organ dysfunction syndrome: Syndrome, metaphor, and unsolved clinical challenge. Crit. Care Med. 49(9), 1402–1413 (2021).
Hausenloy, D. J. & Yellon, D. M. Ischaemic conditioning and reperfusion injury. Nat. Rev. Cardiol. 13(4), 193–209 (2016).
Konstantinov, I. E. et al. The remote ischemic preconditioning stimulus modifies inflammatory gene expression in humans. Physiol. Genom. 19(1), 143–150 (2004).
Mollet, I. et al. Pilot study in human healthy volunteers on the mechanisms underlying remote ischemic conditioning (RIC)—Targeting circulating immune cells and immune-related proteins. J. Neuroimmunol. 367, 577847 (2022).
Gassanov, N., Nia, A. M., Caglayan, E. & Er, F. Remote ischemic preconditioning and renoprotection: From myth to a novel therapeutic option?. J. Am. Soc. Nephrol. 25(2), 216–224 (2014).
Heusch, G., Botker, H. E., Przyklenk, K., Redington, A. & Yellon, D. Remote ischemic conditioning. J. Am. Coll. Cardiol. 65(2), 177–195 (2015).
Kleinbongard, P., Skyschally, A. & Heusch, G. Cardioprotection by remote ischemic conditioning and its signal transduction. Pflugers Arch. 469(2), 159–181 (2017).
Heusch, G. Myocardial ischaemia–reperfusion injury and cardioprotection in perspective. Nat. Rev. Cardiol. 17(12), 773–789 (2020).
Cohen, M. V., Yang, X. M., Liu, G. S., Heusch, G. & Downey, J. M. Acetylcholine, bradykinin, opioids, and phenylephrine, but not adenosine, trigger preconditioning by generating free radicals and opening mitochondrial K(ATP) channels. Circ. Res. 89(3), 273–278 (2001).
Joseph, B. et al. Secondary brain injury in trauma patients: The effects of remote ischemic conditioning. J. Trauma Acute Care Surg. 78(4), 698–705 (2015).
Leung, C. H. et al. Remote ischemic conditioning prevents lung and liver injury after hemorrhagic shock/resuscitation: Potential role of a humoral plasma factor. Ann. Surg. 261(6), 1215–1225 (2015).
Jan, W. C., Chen, C. H., Tsai, P. S. & Huang, C. J. Limb ischemic preconditioning mitigates lung injury induced by haemorrhagic shock/resuscitation in rats. Resuscitation 82(6), 760–766 (2011).
Lv, J., Yan, W., Zhou, J., Pei, H. & Zhao, R. Per- and post-remote ischemic conditioning attenuates ischemic brain injury via inhibition of the TLR4/MyD88 signaling pathway in aged rats. Exp. Brain Res. 239(8), 2561–2567 (2021).
Huang, J. et al. Remote ischemic post-conditioning improves myocardial dysfunction via the risk and safe pathways in a rat model of severe hemorrhagic shock. Shock 49, 460–465 (2018).
Loukogeorgakis, S. P. et al. Remote ischemic preconditioning provides early and late protection against endothelial ischemia–reperfusion injury in humans: Role of the autonomic nervous system. J. Am. Coll. Cardiol. 46(3), 450–456 (2005).
Panisello-Rosello, A., Rosello-Catafau, J. & Adam, R. New insights in molecular mechanisms and pathophysiology of ischemia–reperfusion injury 2.0: An updated overview. Int. J. Mol. Sci. 22(1), 28 (2020).
Laichalk, L. L., Danforth, J. M. & Standiford, T. J. Interleukin-10 inhibits neutrophil phagocytic and bactericidal activity. FEMS Immunol. Med. Microbiol. 15(4), 181–187 (1996).
Webb, N. J., Myers, C. R., Watson, C. J., Bottomley, M. J. & Brenchley, P. E. Activated human neutrophils express vascular endothelial growth factor (VEGF). Cytokine 10(4), 254–257 (1998).
Medford, A. R. & Millar, A. B. Vascular endothelial growth factor (VEGF) in acute lung injury (ALI) and acute respiratory distress syndrome (ARDS): Paradox or paradigm?. Thorax 61(7), 621–626 (2006).
Yoshie, O. & Matsushima, K. CCR4 and its ligands: From bench to bedside. Int. Immunol. 27(1), 11–20 (2015).
Katakura, T., Miyazaki, M., Kobayashi, M., Herndon, D. N. & Suzuki, F. CCL17 and IL-10 as effectors that enable alternatively activated macrophages to inhibit the generation of classically activated macrophages. J. Immunol. 172(3), 1407–1413 (2004).
Alganabi, M. et al. Remote ischemic conditioning causes CD4 T cells shift towards reduced cell-mediated inflammation. Pediatr. Surg. Int. 38(5), 657–664 (2022).
Richter, J. R. et al. Macrophage-derived chemokine (CCL22) is a novel mediator of lung inflammation following hemorrhage and resuscitation. Shock 42(6), 525–531 (2014).
Abi-Younes, S., Si-Tahar, M. & Luster, A. D. The CC chemokines MDC and TARC induce platelet activation via CCR4. Thromb. Res. 101(4), 279–289 (2001).
Jeong, S. I., Choi, B. M. & Jang, S. I. Sulforaphane suppresses TARC/CCL17 and MDC/CCL22 expression through heme oxygenase-1 and NF-kappaB in human keratinocytes. Arch. Pharm. Res. 33(11), 1867–1876 (2010).
Leung, C. H. et al. Nuclear factor (erythroid-derived 2)-like 2 regulates the hepatoprotective effects of remote ischemic conditioning in hemorrhagic shock. Antioxid. Redox Signal. 30(14), 1760–1773 (2019).
Nielsen, M. B. et al. Dynamics of circulating dendritic cells and cytokines after kidney transplantation-No effect of remote ischaemic conditioning. Clin. Exp. Immunol. 206(2), 226–236 (2021).
Gedik, N. et al. Potential humoral mediators of remote ischemic preconditioning in patients undergoing surgical coronary revascularization. Sci. Rep. 7(1), 12660 (2017).
Hummitzsch, L. et al. Effects of remote ischemic preconditioning (RIPC) and chronic remote ischemic preconditioning (cRIPC) on levels of plasma cytokines, cell surface characteristics of monocytes and in-vitro angiogenesis: A pilot study. Basic Res. Cardiol. 116(1), 60 (2021).
Dewitte, K. et al. Role of oxidative stress, angiogenesis and chemo-attractant cytokines in the pathogenesis of ischaemic protection induced by remote ischaemic conditioning: Study of a human model of ischaemia–reperfusion induced vascular injury. Pathophysiology 26(1), 53–59 (2019).
Iliodromitis, E. K., Cohen, M. V. & Downey, J. M. Remote ischemic conditioning: More explanations and more expectations. Basic Res. Cardiol. 117(1), 49 (2022).
Meybohm, P. et al. A multicenter trial of remote ischemic preconditioning for heart surgery. N. Engl. J. Med. 373(15), 1397–1407 (2015).
Hausenloy, D. J. et al. Effect of remote ischaemic conditioning on clinical outcomes in patients with acute myocardial infarction (CONDI-2/ERIC-PPCI): A single-blind randomised controlled trial. Lancet 394(10207), 1415–1424 (2019).
Mollet, I., Marto, J. P., Mendonca, M., Baptista, M. V. & Vieira, H. L. A. Remote but not distant: A review on experimental models and clinical trials in remote ischemic conditioning as potential therapy in ischemic stroke. Mol. Neurobiol. 59(1), 294–325 (2022).
Park, E. et al. Remote ischemic conditioning improves outcome independent of anesthetic effects following shockwave-induced traumatic brain injury. IBRO Rep. 8, 18–27 (2020).
Huber-Lang, M., Lambris, J. D. & Ward, P. A. Innate immune responses to trauma. Nat. Immunol. 19(4), 327–341 (2018).
Kottenberg, E. et al. Interference of propofol with signal transducer and activator of transcription 5 activation and cardioprotection by remote ischemic preconditioning during coronary artery bypass grafting. J. Thorac. Cardiovasc. Surg. 147(1), 376–382 (2014).
Dezfulian, C. et al. Biochemical signaling by remote ischemic conditioning of the arm versus thigh: Is one raise of the cuff enough?. Redox Biol. 12, 491–498 (2017).
Johansson, P. I., Stensballe, J. & Ostrowski, S. R. Shock induced endotheliopathy (SHINE) in acute critical illness—A unifying pathophysiologic mechanism. Crit. Care 21(1), 25 (2017).
Rassaf, T. et al. Plasma nitrite reserve and endothelial function in the human forearm circulation. Free Radic. Biol. Med. 41(2), 295–301 (2006).
Lieder, H. R. et al. Vago-splenic axis in signal transduction of remote ischemic preconditioning in pigs and rats. Circ. Res. 123(10), 1152–1163 (2018).
Zellweger, R., Ayala, A., DeMaso, C. M. & Chaudry, I. H. Trauma-hemorrhage causes prolonged depression in cellular immunity. Shock 4(2), 149–153 (1995).
Vulliamy, P. et al. Alterations in platelet behavior after major trauma: Adaptive or maladaptive?. Platelets 32(3), 295–304 (2021).
Lieder, H. R. et al. Platelet-mediated transfer of cardioprotection by remote ischemic conditioning and its abrogation by aspirin but not by ticagrelor. Cardiovasc. Drugs Ther. https://doi.org/10.1007/s10557-022-07345-9 (2022).
Funding
This work was funded by the Canadian Institutes of Health Research #23766, the Physicians Services Incorporated Foundation, Defence Research and Development Canada, Department of National Defence, and Canadian Institute for Military and Veteran Health Research (CIMVHR). CHL was supported by funds from the Rae Fellowship, St. Michael’s Hospital Foundation and Mitacs.
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C.H.L.: Conception and design, acquisition and analysis of data; interpretation of data; drafted the work. S.B.R.: Conception, acquisition and analysis of data; interpretation of data; drafted the work. S.T.: Acquisition and analysis of data. S.R.: Conception, acquisition and analysis of data; interpretation of data; drafted the work. A.B.: Acquisition and analysis of data. M.A.: Acquisition and analysis of data; interpretation of data; drafted the work. O.D.R.: Conception and design, acquisition and analysis of data; interpretation of data; drafted the work.
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Leung, C.H., Rizoli, S.B., Trypcic, S. et al. Effect of remote ischemic conditioning on the immune-inflammatory profile in patients with traumatic hemorrhagic shock in a randomized controlled trial. Sci Rep 13, 7025 (2023). https://doi.org/10.1038/s41598-023-33681-3
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DOI: https://doi.org/10.1038/s41598-023-33681-3
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