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Warm ischemia provokes inflammation and regional hypercoagulability within the heart during off-pump coronary artery bypass: a possible target for serine protease inhibition

Department of Cardiac Surgery, University of Maryland School of Medicine, Baltimore, MD, United States

Received 5 September 2007; received in revised form 13 November 2007; accepted 18 November 2007.

^_* Corresponding author. Address: Division of Cardiac Surgery, N4W94 22 S. Greene Street, Baltimore, MD 21201, United States. Tel.: +1 410 328 5842; fax: +1 410 328 2750. (Email: rposton{at}smail.umaryland.edu).

	Abstract

Top Abstract 1. Introduction 2. Methods 3. Results 4. Discussion Appendix A References

 
Objective: Accumulating evidence suggests that a hypercoagulable state influences early graft failure after off-pump coronary artery bypass (OPCAB). We hypothesized that regional myocardial ischemia caused by obligatory periods of coronary occlusion during OPCAB is an important trigger for this prothrombotic state. Methods: Using a series of biomarkers, 60 consecutive patients undergoing OPCAB were monitored for myocardial injury (myoglobin), inflammation (TNF-, IL-8) and thrombosis (thrombin generation-F1.2, contact activation pathway-FXII-a, platelet derived microparticles-via flow cytometry). The transcardiac gradients of these markers were determined by assaying both arterial and coronary sinus blood just after protamine administration. Intramyocardial pH was monitored continuously during coronary occlusion in a subset (N = 30 grafts, 11 patients). The influence of management strategies affecting hemostasis (e.g. antiplatelet therapy, anti-fibrinolytics, peak activated clotting time (ACT) during heparinization) was analyzed. Results: Ischemic injury, depicted by the transcardiac myoglobin gradient, significantly correlated with intramyocardial acidosis during coronary occlusion (R = 0.96, p < 0.0001) and predicted the transcardiac gradients of TNF- (R = 0.83, p < 0.001) and F1.2 (R = 0.72, p < 0.0001). Transcardiac F1.2 strongly correlated with TNF- (R = 0.73, p = 0.01) and IL-8 (R = 0.51, p = 0.02). Patients receiving aprotinin (N = 20) showed significantly lower transcardiac gradients for myoglobin (4.1 ± 7.5% vs 72.9 ± 108.8% change, p = 0.002), F1.2 (31 ± 37% vs 89 ± 149%, p = 0.03), FXII-a (2.6 ± 4.1% vs 19.2 ± 34%, p = 0.04) and microparticles (7 ± 3.9% vs 12.9 ± 8%, p = 0.01). Conclusions: Strong correlations between myocardial ischemia and the transcardiac gradients of markers for inflammation and thrombosis suggest that even brief episodes of coronary occlusion in the beating heart may have pathophysiologic consequences. Aprotinin, but not other factors that influence the coagulation system, appears to mitigate this process during OPCAB.

Key Words: Coronary artery bypass • Hypercoagulabilty • Ischemia • OPCAB • Aprotinin

	1. Introduction

Top Abstract 1. Introduction 2. Methods 3. Results 4. Discussion Appendix A References

 
Off-pump coronary artery bypass graft surgery (OPCAB) circumvents the need for global myocardial ischemia inherent with CABG performed on the arrested heart and requires only brief periods of regional ischemia during the coronary anastomoses. On occasion, this regional ischemia is tolerated poorly and results in arrhythmias and myocardial stunning, but this risk is minimal when coronary occlusion is kept to <10–15 min per anastomosis [1]. As a result, randomized studies comparing off- vs on-pump CABG have documented improvements in myocardial injury and early hemodynamics after OPCAB [2–4]. However, the impact of regional warm ischemia on inflammation and coagulation after OPCAB has not been studied.

Thrombin mediates a variety of inflammatory and thrombotic processes associated with ischemia-reperfusion injury. In prior OPCAB studies, we noted a burst of thrombin production from the heart minutes after protamine administration [5], reminiscent of the well-described ‘rebound hypercoagulable state’ that occurs in unstable angina patients after heparin withdrawal [6]. The prothrombin cleavage product, F1.2, has been established as a surrogate marker of a prothrombotic state through significant associations with the risk of acute vein graft failure [7], myocardial injury [8] after CABG, and major adverse cardiovascular events [9]. Thrombin production can be mitigated by enhanced antiplatelet therapy [10] as well as the use of higher heparin doses during cardiopulmonary bypass [11]. Aprotinin, used primarily for its hemostatic properties, has been suggested to have anti-thrombotic effects via inhibition of the thrombin receptor, protease activated receptor-1 (PAR-1) [12–15]. Although other PAR-1 antagonists have been documented to reduce major adverse cardiovascular events [16], there are few clinical reports to suggest an anti-thrombotic effect from aprotinin despite administration to thousands of on-pump CABG patients. In contrast to conventional CABG, we hypothesized that OPCAB creates a series of pathologic findings in response to regional warm ischemia (e.g. local activation of thrombin, platelets and the contact activation pathway) that provide a more favorable model for demonstrating the clinical effects of PAR-1 inhibition by aprotinin.

	2. Methods

Top Abstract 1. Introduction 2. Methods 3. Results 4. Discussion Appendix A References

 
2.1 Patient selection and enrollment
Following IRB approval (UMB protocol #25350), 60 consecutive patients underwent off-pump CABG at our institution. All subjects provided informed consent before enrollment into this prospective, observational study of patients undergoing OPCAB with no aprotinin (n = 40) or off-pump CABG with a modified full-dose regimen of aprotinin (n = 20), as previously described [15]. Assignment to the aprotinin group was nonrandomized. Hemodynamic instability, acute coronary syndromes or situations in which complete revascularization was not possible served as exclusion criteria. Patients with chronic renal insufficiency (creatinine >2.0 mg/dl), and allergy to radiographic contrast were also excluded from enrollment. Demographics, preoperative risk factors and medications, intra- and postoperative data were prospectively recorded into a relational database.

2.2 Treatments
A modified full-dose regimen was used as previously described. Heparin dose was calculated by protamine titration using a HMS heparin assay (0.0–2.5 mg/kg cartridge, Medtronic, Minneapolis, Minnesota) to maintain levels greater than 2 µg/ml and a kaolin-based ACT greater than 300 s. The heparin effect was partially reversed by administering half the dose of protamine calculated by the HMS device. The algorithm for intraoperative and postoperative blood product transfusions was based on thrombelastography analysis, as described [17]. All patients received aspirin (325 mg orally each morning and within 6 h after intensive care unit arrival) as the sole postoperative platelet inhibitor. Glucose levels were maintained at less than 150 mg/dl using routine insulin infusions.

2.3 Surgery and perioperative management
After median sternotomy, the left internal thoracic artery was used in all patients; the saphenous vein was harvested using an endoscopic (VasoView6 ^®, Guidant Systems, Inc., Minneapolis, MN) or open approach, based on anatomical considerations. Conduits were stored in heparinized saline after harvest. Proximal anastomoses were performed using a partial occluding aortic clamp. All distal anastomoses were facilitated by suction-based exposure and stabilizing devices (Octopus 4.3 ^®, Medtronic, Inc., Minneapolis, MN) without intracoronary shunts. Shed mediastinal blood was collected intraoperatively using a cellsaving device (Cobe BRAT 2; Arvada, CO), processed, and retransfused.

2.4 Intraoperative blood flow analysis
Blood flow and flow waveform were measured in each graft using transit time ultrasound (Transonic, Inc., Ithica, NY). Waveforms were analyzed for pulsatility index and percentage diastolic flow using digital data acquisition software (WinDaq^TM, DATAQ Instruments, Inc., Dayton, OH).

2.5 Blood sample collection
Blood samples, collected in tubes containing 3.2% citrate, were obtained preoperatively from the arterial line. Postoperatively, 30 min after heparin reversal with half dose protamine, blood was obtained from the systemic arterial line and coronary sinus (CS). Additional systemic blood was collected on postoperative days 1 and 3. Platelet-poor plasma was obtained by rapid centrifugation (2000 x g) and stored at –80 °C.

2.6 Myocardial injury and acidosis
Cardiac troponin I (Tn-I) and myoglobin were both assessed using ELISA kits (Life Diagnostics, Inc., West Chester, PA). Regional (i.e. anterior and posterior ventricular wall) changes in pH were monitored in real time using the Khuri^TM pH monitoring system (Terumo Corp, Tokyo Japan).

2.7 Assays for coagulation and inflammation
Thrombin formation was evaluated by assaying postoperative systemic and CS samples for the presence of prothrombin fragment 1.2 (F1.2) (Dade Behring, Marburg, Germany). The contact activation pathway was evaluated by assaying FXII-a (American Diagnostica, Inc., Stamford, CT). Inflammation was assessed via interleukin-8 (IL-8) and tumor necrosis factor- (TNF-) using ELISA (Bender MedSystems, Vienna, Austria). Comparison of the concentration of these markers in the CS to a simultaneously obtained aortic (Ao) sample allowed for calculation of %transcardiac change as follows: (CS – Ao)/Ao x 100.

2.8 Assays for platelet function
2.8.1 Thrombelastography (TEG^TM, Haemoscope, Niles, IL)
Maximum amplitude (MA) of the TEG trace was measured after 30 s of activation by kaolin or tissue factor (0.0001% Innovin^®, Dade-Behring).

2.8.2 Whole blood aggregometry (Chronolog, Hawerton, PA)
Impedance changes () were assessed at 6 min following the addition of 1 µg/ml and 5 µg/ml collagen as described [7].

2.8.3 Whole blood flow cytometry (Becton-Dickinson FACScan, Franklin Lakes, NJ)
Citrated blood samples were diluted with modified Tyrode Buffer containing 5 mM GPRP (Centerchem Inc., Norwalk, CT) and then incubated with antibodies against CD41-FITC (Serotec, Raleigh, NC) and AnnexinV-APC (BD Biosciences, San Jose, CA). After 20 min incubation, the samples were fixed with 1% paraformaldehyde and stored at 4 °C until analysis within 72 h by FACS. Both, forward scatter and sideward light scatter were set at logarithmic gain, and platelet derived microparticles were identified. The %annexin-positive microparticle events compared to total CD41 positive events was calculated as described [18].

2.9 Endothelial integrity
Surplus segments from each bypass conduit were stored in balanced salt solution at room temperature for 30–60 min, embedded in cutting compound (Tissue-Tek^® O.C.T., Redding, CA) and then frozen in liquid nitrogen. Four separate 5 µm thick sections were assessed for the expression of an EC marker, CD31 (R&D System, Inc., Minneapolis, MN) using immunohistochemistry. The %vessel circumference positive for CD31 was calculated in each section using image analysis software (Bioquant Nova Prime, Nashville, TN) and EC integrity defined by the average %CD31 staining for all sections analyzed [7].

2.10 Graft patency
Bypass graft patency was determined by blinded review of a 64 detector row, CT angiography (CTA) scan (420 ms rotation, 100–150 ml contrast agent IV at 5 cc/s) using retrospective ECG gating. Patency was defined as any flow through the entire graft regardless of the presence of stenosis. The graft was classified as nonpatent if a stump was seen or if there was no contrast in an area known by operative report to contain a graft.

2.11 Statistics
The primary endpoint of this trial was a comparison of markers of regional hypercoagulability and inflammation after OPCAB with and without the use of aprotinin. A previous investigation of aprotinin by our group [15] showed a three-fold decrease in transcardiac F1.2 compared to control. Therefore, 20 patients per group would provide a >80% power to detect a similar difference in F1.2 and other markers in this cohort at p = 0.05, assuming a standard deviation of 25%¹ . Groups were compared by means of the unpaired Student's t-test for continuous variables and the Fisher's exact test for categorical variables. The area under the concentration–time curves was compared for markers that were measured serially (e.g. cTn-I). Correlations were examined using linear regression for parametric data. Statistical analysis was performed using the InStat^TM statistical package with the assistance of a biostatistician.

	3. Results

Top Abstract 1. Introduction 2. Methods 3. Results 4. Discussion Appendix A References

 
3.1 Patient population
OPCAB patients that received aprotinin were similar to the control group in all analyzed clinical variables (Table 1 ) and received equal number of grafts per group (3.1 ± 0.4 vs 3.2 ± 0.5). None of the patients in this cohort required conversion to on-pump techniques and 100% underwent follow-up of graft patency prior to hospital discharge. There were no deaths and no evidence of hypersensitivity reaction to aprotinin in any of the patients during the study.

View larger version (8K): [in this window] [in a new window]   Fig. 1. Correlation between regional acidosis and myoglobin release. Tissue pH was monitored during the distal anastomoses performed during OPCAB. We noted varying degrees of intramyocardial acidosis despite coronary occlusion times that were nearly identical between anastomoses and always <15 min. Myoglobin release was measured at the completion of OPCAB, 30 min after protamine administration. A transcardiac gradient was calculated by analyzing myoglobin levels from blood samples obtained simultaneously from the aorta and coronary sinus. A strong linear correlation between the mean regional pH change intraoperatively and transcardiac myoglobin release postoperatively.

View larger version (10K): [in this window] [in a new window]   Fig. 2. Myocardial injury after OPCAB in the aprotinin vs control groups. Myocardial injury was measured by analyzing the transcardiac gradient of myoglobin at 30 min following the completion of OPCAB and by comparing the area under the concentration–-time curve of cardiac troponin I (cTn-I) levels measured at 6, 24 and 72 h. While transcardiac myoglobin release was significantly reduced in the aprotinin vs control group, cTn-I was not significantly different.

View larger version (12K): [in this window] [in a new window]   Fig. 3. Differences in thrombosis markers in the aprotinin and control groups. Thrombin production and the contact activation pathway were monitored after OPCAB by measuring the transcardiac gradients of F1.2 and FXII-a. Platelet activation within the coronary circulation was assessed by determining the proportion of CD41+, Annexin+ microparticles released from the heart, normalized against the number of platelets in the sample. The aprotinin group showed significantly reduced thrombin formation (F1.2), inhibition of contact activation (FXII-a) and reduced microparticle formation within the heart after OPCAB.

View larger version (9K): [in this window] [in a new window]   Fig. 4. Increased risk of the thrombin burst in patients with low flow bypass grafts. Most patients showed at least some increase in F1.2 in the coronary sinus vs the aortic blood after OPCAB. However, the ‘thrombin burst’, defined as a two-fold or greater transcardiac increase in F1.2, was noted in only 18 (30%) patients. Mean blood flow within the venous grafts was significant reduced in those patients who developed the thrombin burst at the end of the case compared to those with F1.2 levels less than this threshold.

	4. Discussion

Top Abstract 1. Introduction 2. Methods 3. Results 4. Discussion Appendix A References

We also analyzed the impact of different therapeutic approaches employed in our cohort that might have an influence on hemostasis and thrombotic risk. A portion of our cohort was receiving clopidogrel until surgery and/or developed a higher intraoperative ACT level (e.g. >400 s). In these patients, we found no difference in the regional production of thrombin or any other marker compared to those treated with aspirin monotherapy and intraoperative ACT levels <400 s. These findings contradict other reports suggesting that these strategies are effective ways to reduce thrombin production [10,11]. However, these investigations analyzed thrombin production in the systemic circulation. Analysis of CS blood provides a more sensitive and specific assay of events within the upstream coronary circulation [20,21]. We speculate that the application of this method in our study improved our pathophysiological insight into conditions that influence the risk of graft thrombosis after OPCAB.

Aprotinin administered prior to skin incision at full dose was associated with a significant reduction in the transcardiac gradient of the coagulation markers that were analyzed when compared to the control group. Activation of PAR-1 is likely an important avenue through which the platelet is able to respond to thrombin and participate in the feedback thrombin burst necessary for graft thrombosis. Aprotinin has been shown to block PAR-1 in vitro [12] and in vivo [14]. Nevertheless, conventional wisdom suggests that aprotinin is a prothromobic agent because of its potent hemostatic effects. Establishing a clear definition of the hypercoagulable state is a vital step towards better understanding the relationship between the use of aprotinin and risk of thrombosis.

On the other hand, aprotinin also inhibits fibrinolysis, an important mechanism through which the coronary circulation keeps thrombus formation in check. This has raised considerable concern that aprotinin might increase the risk of thrombosis [22]. The safety of aprotinin remains an important and controversial issue in cardiothoracic surgery, with conflicting evidence arising from randomized clinical trials [23] and observational studies [22] during on-pump CABG regarding issues such as renal dysfunction and even death. However, these nonrandomized observational trials have recently been reviewed by an FDA advisory panel and deemed statistically flawed in their analysis. As a result of the reanalysis of the raw data from these studies, the panel reached significantly more favorable conclusions regarding the safety of aprotinin² . There has also been a more recent meta analysis by the Cochrane group [24] looking at over 200 randomized controlled trials and over 20,000 patients that found no increased risk of myocardial infarction, stroke, graft thrombosis or death with aprotinin use. On the other hand, renal dysfunction does appear to be a consistent risk that emerges in studies analyzing the safety of aprotinin use. The continued marketing of aprotinin for cardiac surgery is likely going to require further more in depth study of this important issue.

Another plausible approach to investigate would have been to prevent warm ischemic injury to the myocardium by the routine use of intracoronary shunts during the distal anastomoses. Shunts were not used in this cohort out of concern for injury to the coronary endothelium during placement [25]. Therefore, we are not able to address the merits of this idea.

In previous studies, our group has demonstrated that endothelial disruption in the bypass conduit directly relates to regional thrombin production after OPCAB [7]. In this study, we add lower intraluminal blood flow within the grafts as an additional risk factor (Fig. 4). Platelets and coagulation factors are known to react to abnormalities in flow and endothelium by participating in thrombin generation. There is not likely to be a systematic difference in the endothelial quality or blood flow within the coronary circulation during on- and off-pump CABG. Therefore, technical differences between these procedures may help explain the discrepancy in thrombin production. Warm myocardial ischemia is an issue that is unique to OPCAB and has been shown to be a more potent stimulant of thrombin production than cold ischemia in a variety of experimental and clinical studies [26]. We feel that our data point to this issue is a primary stimulus of the hypercoagulable state after OPCAB.

4.1 Limitations
The main limitations of this study were the small number of subjects that were analyzed and nonrandomized study design. Given insufficient numbers, we were unable to perform a multivariate analysis to confirm that aprotinin was an independent predictor of regional hypercoagulability and were underpowered to establish a link to hard endpoints such as postoperative saphenous vein graft (SVG) failure and myocardial infarction (MI). Our study screened for factors that are most likely to influence regional hypercoagulability such as anastomotic and endothelial quality of each SVG and platelet function using three separate assays. However, the nonrandomized use of aprotinin is likely to have introduced confounding factors that remain unaccounted for in our analysis. In addition, the clinical intrusiveness of the protocol limited our coronary sinus measurements to a single 30 min time point after protamine administration, which may have underestimated the incidence of the thrombin burst reaction after OPCAB. Finally, because this study was performed only at a single center, generalizability to other centers may be limited by institution specific practices that effect thrombin production such as the aggressive use of the cell saver during OPCAB and SVG harvesting and preparation techniques. For these reasons, our findings are best interpreted as ‘hypothesis generating’ pending the completion of an ongoing prospective clinical trial to investigate the relationship between regional hypercoagulability markers and early graft failure.

4.2 Conclusion
In the present study, we demonstrated that intramyocardial acidosis following obligatory periods of warm ischemia during OPCAB was associated with the activation of a regional hypercoagulable and inflammatory state. Intraoperative aprotinin use during OPCAB was found to attenuate these findings, perhaps via inhibitory effects on PAR-1 and/or other serine proteases. These data support further investigation of a novel role for aprotinin (or other PAR-1 antagonists) during surgical revascularization: as an adjunct to help abrogate the postoperative hypercoagulable state after OPCAB, and potentially improve early graft patency.

	Appendix A

Top Abstract 1. Introduction 2. Methods 3. Results 4. Discussion Appendix A References

 
Conference discussion

Dr A. Calafiore (Catania, Italy): I want to congratulate the authors for this paper that focuses on the regional modifications caused by warm ischemia during myocardial revascularization on a beating heart without cardiopulmonary bypass. The evidence of myocardial pH drop with an increase of myoglobin gradient and of a prothrombotic and inflammatory state suggests that even short periods of short-lasting local myocardial ischemia are able to cause adverse effects, even if subclinical. However, as pointed out by the authors, many questions remain to be answered; for instance, the role of aggressive use of the Cell Saver on thrombin production, as well as the small number of patients, together with the lack of randomization. Furthermore, the conflicting results of randomized and observational studies on the use of aprotinin in cardiac surgery raise concerns about its safety.

I would like to add other aspects that would be interesting to explore. Even if the authors did not use them in order to avoid any endothelial damage, the use of intracoronary shunts needs to be explored to evaluate a possible strategy to limit cellular damage. Another variable can be the limited but possible cellular damage related to epicardial suction during stabilization of the coronary artery or during exposure of the inferolateral wall with a suction cup.

I would like to ask whether these findings can have a clinical impact. Provided that aprotinin is not available in many countries, do you think your results confirm that off-pump surgery is still the method that provokes less myocardial injury? Did you perform a similar study in on-pump patients operated on with global ischemia? As surgery is always a compromise between the best results available and the lowest damage possible, can we be satisfied by our results, or can this study suggest to us that we can hope for further improvements?

Dr Poston: Your question about on-pump surgery was previously investigated by our group. We looked at the markers of thrombin production, contact activation and platelet activation in the coronary sinus following on-pump surgery and found it was reduced compared to off-pump. Warm ischemia is the most likely trigger for this additional activation of coagulation following off-pump compared to on-pump. On-pump also involves a greater level of intraoperative heparinization and that might be a difference to consider between procedures, but we didn’t find any influence from the level of heparinization on the markers during off-pump. Another possibility would be that platelet function is more intact following off-pump vs on-pump CABG and that might trigger a greater activation of coagulation. However, we haven’t found any relationship between a series of platelet function tests and these coronary sinus markers.

So the best avenue is to try to avoid warm ischemia, and coronary shunts are one way to accomplish that. Nowadays with smaller coronary targets, that's a tough option as a routine to shunt every single coronary. Aprotinin, as you mentioned, is too controversial of a drug at this point to expect that it is going to be used as an adjuvant to prevent hypercoagulability and graft failure after off-pump CABG. Perhaps the best avenue is to use a PAR-1-specific antagonist, and then you don’t get into the potential complications of inhibiting other potentially protective serine proteases such plasmin. We also need to consider the risk of developing postoperative renal insufficiency after aprotinin use. I appreciate your comments and they are well taken.

	Footnotes

 
^\#9734; Presented at the 21st Annual Meeting of the European Association for Cardio-thoracic Surgery, Geneva, Switzerland, September 16–19, 2007.

^{\#9734;\#9734;} R.P. is funded by grants from the NIH (R01HL084080), American Heart Association (Scientist Development Grant, 043518N), University of Maryland (intramural grant), Tobacco Restitution Fund at the University of Maryland and Bayer Pharmaceutical Corp (phase IV grant).

¹ http://hedwig.mgh.harvard.edu/sample_size/size.html#parallel.

² http://www.fda.gov/OHRMS/DOCKETS/AC/07/slides/2007-4316s1-12-FDA-Levenson.ppt, accessed on 10/15/07.

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