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Rheolytic thrombectomy during percutaneous revascularization for acute myocardial infarction: Experience with the AngioJet catheter
Rheolytic thrombectomy during percutaneous revascularization for acute myocardial infarction: Experience with the AngioJet catheter Jose A. Silva, MD,a Stephen R. Ramee, MD,a David J. Cohen, MD, MSc,b Joseph P. Carrozza, MD,b Jeffrey J. Popma, MD,c Alexandra A. Lansky, MD,d Kim Dandreo, BS,b Donald S. Baim, MD,c Barry S. George, MD,e Daniel J. McCormick, DO,f Cindy M. Setum, PhD,g and Richard E. Kuntz, MD, MScc New Orleans, La, Boston, Mass, New York, NY, Columbus, Ohio, Philadelphia, Pa, and Minneapolis, Minn
Background Although balloon angioplasty and stenting are effective in the treatment of acute myocardial infarction (MI), reduced coronary flow and distal embolization frequently complicate interventions when thrombus is present. Adjunctive treatment with mechanical thrombectomy devices may reduce these complications.
Methods and Results We evaluated the angiographic and clinical outcomes of 70 patients with acute MI (16% with cardiogenic shock) and with angiographically evident thrombus who were treated with AngioJet rheolytic thrombectomy followed by immediate definitive treatment. Procedure success (residual diameter stenosis <50% and Thrombolysis in Myocardial Infarction [TIMI] flow ≥2 after final treatment) was achieved in 93.8%. Clinical success (procedure success without major in-hospital cardiac events) was achieved in 87.5%, with an in-hospital mortality rate of 7.1%. Final TIMI 3 flow was achieved in 87.7%. AngioJet treatment resulted in a mean thrombus area reduction from 73.2 ± 64.6 mm2 at baseline to 15.5 ± 30.1 post-thrombectomy (P < .001). Subsequent definitive treatment included stenting in 67% and balloon angioplasty alone in 26% of patients. Procedural complications included distal embolization in six patients and perforation in two patients. There were no further major adverse events during 30-day follow-up. Conclusion Rheolytic thrombectomy can be performed safely and effectively in patients with acute MI, allowing for immediate definitive treatment in thrombus-containing lesions. (Am Heart J 2001;141:353-9.)
Sudden thrombotic occlusion is responsible for acute myocardial infarction (MI) in the majority of patients, and rapid restoration of normal coronary flow preserves myocardial function and improves long-term prognosis.1 Early reperfusion can be accomplished with pharmacologic thrombolysis or primary percutaneous angioplasty. Primary angioplasty has been shown to provide higher rates of Thrombolysis in Myocardial Infarction (TIMI) 3 coronary flow and preservation of left ventricular function compared with pharmacologic thrombolysis but is limited by higher rates of reocclusion, recurrent infarction, and restenosis compared with elective angioplasty.2-4 The presence of thrombus in acute MI may be From the aAlton Ochsner Medical Foundation, New Orleans, La, bBeth Israel Deaconess Medical Center and cBrigham and Women’s Hospital, Boston, Mass, dLenox Hill Hospital, New York, NY, eMid-Ohio Cardiology Consultants, Columbus, Ohio, the fCardiology Consultants of Philadelphia, Philadelphia, Pa, and gPossis Medical, Minneapolis, Minn. Submitted March 16, 2000; accepted November 17, 2000. Reprint requests: Richard E. Kuntz, MD, MSc, Cardiovascular Division, Brigham and Women’s Hospital, 75 Francis St, Boston, MA 02215. E-mail: [email protected] Copyright © 2001 by Mosby, Inc. 0002-8703/2001/$35.00 + 0 4/1/112997 doi:10.1067/mhj.2001.112997
a major factor responsible for the development of these complications.5-9 Although thrombus removal before definitive catheter-based intervention in acute MI may be desirable, antecedent or adjunctive pharmacologic thrombolysis has not been shown to improve the clinical outcomes of coronary intervention.10-12 Strategies using combined reduced-dose thrombolysis and subsequent intervention, however, show promise.13 The use of glycoprotein IIb/IIIa receptor antagonists as an adjunctive pharmacologic regimen to direct angioplasty has been shown to reduce the need for urgent repeat interventions.14-16 Mechanical removal of thrombus with transluminal extraction atherectomy (TEC catheter, Interventional Technologies, San Diego, Calif) may obviate the problems of systemic thrombolysis, but treatment is associated with suboptimal outcomes in thrombuscontaining lesions.17 AngioJet rheolytic thrombectomy (Possis Medical, Minneapolis, Minn) is a catheter-based method for thrombus removal. High-velocity saline solution jets are used to create a localized low-pressure zone at the distal catheter tip (Bernoulli effect), which results in the maceration and removal of thrombus through an exhaust
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Figure 1
AngioJet LF140 rheolytic thrombectomy catheter, distal tip.
lumen. The use of rheolytic thrombectomy in the treatment of non-MI thrombus-containing coronary lesions has been previously reported.18-20 The purpose of the current study was to assess the safety and clinical efficacy of adjunctive rheolytic thrombectomy during percutaneous revascularization for acute MI.
a mobile or fixed intraluminal filling defect outlined or stained by contrast dye; and target lesion with at least 70% diameter stenosis. Patients were excluded if they had received thrombolytic therapy within 24 hours of the intended AngioJet procedure.
Methods
On arrival to the emergency department, patients received a chewable aspirin (325 mg) along with standard medical treatment for acute MI (intravenous β-blockers, nitrates, etc), at the emergency physician’s discretion. After the diagnosis of acute MI was confirmed and informed consent was obtained, the patient was taken to the cardiac catheterization laboratory for emergency mechanical intervention. Intravenous heparin was given to maintain an activated clotting time of >250 seconds. Platelet IIb/IIIa antagonists were used in 26.2% of patients. The AngioJet LF140 rheolytic catheter is a 5F, dual-lumen, over-the-wire design, as described previously.19 Multiple highvelocity saline solution jets create a localized low-pressure zone at the catheter distal tip (Bernoulli effect), which results in the maceration and removal of thrombus through the effluent lumen (Figure 1). An external piston pump console provides the pressurized pulsatile flow that supplies the jets. After angiographic confirmation of the presence of thrombus, an 8F or 9F guiding catheter was placed in the target vessel, followed by advancement of a 0.014- or 0.018-inch guide wire into the distal vessel. Because transient bradyarrhythmias may occur during rheolytic thrombectomy, a temporary pacing wire was generally placed before treatment. The thrombectomy catheter was then connected to the pump console, flushed, and advanced through the guiding catheter over the guide wire. The pump console was activated by depressing a foot switch, and the catheter was passed slowly across the thrombosed segment in either a distal-to-proximal or proximal-to-distal direction, at a rate of 1 to 2 mm per second. Angiography was obtained after each pass, and additional
Patient population The study population included 70 consecutive patients who had a transmural acute MI within 8 hours of symptom onset and who were enrolled in the Food and Drug Administration (FDA)–approved Vein Graft AngioJet Study-1 (VeGAS 1) or VeGAS 2 acute MI Registry. The protocols were approved by the Institutional Review Boards at each site. Sixteen patients were drawn from VeGAS 1, a 90-patient pilot registry of AngioJet thrombectomy in thrombus-containing saphenous vein bypass grafts and native coronary arteries.18 The remaining 54 patients were drawn from the VeGAS 2 Acute MI Registry, which included 90 patients with angiographic thrombus, treated with AngioJet during an acute MI, and who were seen within 24 hours of symptom onset. Only those patients who were seen within 8 hours of symptom onset were included in the current analysis. Patients analyzed in the current study were identified by a Clinical Events Committee, blinded to the goals of the study, on the basis of evidence of acute MI and symptom onset within 8 hours of intervention. Acute MI was defined as the presence of at least two of the following three criteria: ongoing ischemic pain, ≥0.1 mm ST elevation in two contiguous electrocardiogram (ECG) leads, and elevation of cardiac enzymes to at least two times the upper limit of normal. Patients were also required to meet all the following angiographic inclusion criteria: target lesion reference diameter of at least 2.0 mm; angiographically evident thrombus, defined as
Patient treatment
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passes were performed until all filling defects had been removed or there was no further improvement between passes. In most cases, adjunctive balloon angioplasty or stenting was performed after thrombectomy, with use of standard techniques. Stent sizing was based on a balloon-to-artery ratio of 1.1:1 and inflation pressures of 10 to 20 atmospheres to attain <10% residual stenosis by visual estimate. After final balloon angioplasty or stenting, anticoagulant and antiplatelet therapy included various combinations of aspirin (325 mg daily), ticlopidine (250 mg twice daily for 4 weeks), coumadin (titrated to international normalized ratio of 2.0-2.5), and intravenous heparin for 24 to 48 hours.
Data collection Clinical data were obtained by study coordinators using standardized case report forms, were independently monitored, and were submitted to the data coordinating center (CDAC, Harvard Medical School, Boston, Mass). ECGs were reviewed by the Electrocardiographic Core Laboratory (CDAC, Boston, Mass) blinded to clinical events. Procedural angiograms were submitted to the Angiographic Core Laboratory (Washington Hospital Center, Washington, DC) and analyzed with the CAAS2 system (Pie Medical, Maastricht, The Netherlands). Clinical follow-up was obtained at hospital discharge and at 4 weeks after the index procedure. All events were adjudicated by an independent Clinical Events Committee.
Angiography Cineangiograms of the target lesion were acquired in two angiographic projections before and after thrombectomy treatment and after final treatment. Intracoronary nitroglycerin (50-200 µg) was recommended before angiography, unless contraindicated. The mean reference vessel diameter, minimal lumen diameter (MLD), percent diameter stenosis, and thrombus area were calculated from an average of the two angiographic projections with use of an automated edge detection algorithm (CAAS2). Thrombus area was determined before and after thrombectomy and after final treatment by dividing the vessel in multiple equal segments and calculating the axial length and width of radiolucency in each segment.
End points Procedure success was defined as attainment of TIMI grade 2 or 3 coronary flow and residual diameter stenosis <50% by use of any percutaneous method. The primary end point in this study was clinical success, defined as procedural success without death, major disabling stroke, or emergency bypass surgery during the index hospital stay. Device success was defined as the restoration of TIMI 3 coronary flow and attainment of <50% diameter stenosis after thrombectomy treatment only. Secondary end points included 30-day major adverse cardiovascular events (death, reinfarction, target vessel revascularization) and procedural complications, including perforation, sustained slow flow, distal embolization, bleeding complications, and vascular complications. Sustained slow flow was defined as the occurrence of sudden reduced coronary flow to
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Table I. Baseline demographic and clinical characteristics Characteristic Age (mean ± SD) No. of men Hypertension Dyslipidemia Tobacco use Diabetes mellitus Prior MI Prior coronary artery bypass graft LV ejection fraction (mean ± SD) Duration of chest pain (mean ± SD) Extent of coronary disease 1 vessel 2 vessel 3 vessel Cardiogenic shock Peak creatine kinase (mean ± SD)
N = 70 patients, 70 lesions 60 ± 11 years 66% 48% 24% 42% 19% 37% 22% 44% ± 10% 3.7 ± 1.9 hours 56% 26% 19% 16% 2829 ± 2861 IU/mL
branches or a new abrupt cutoff of distal vessels and branches (by Angiographic Core Lab assessment). Bleeding complications consisted of procedure-related blood transfusions. Vascular complications were defined as the occurrence of hematoma >4 cm, retroperitoneal bleed, false aneurysm, atrioventricular fistula, peripheral ischemia/nerve injury, hemolysis, or hemolytic anemia. Major disabling stroke was defined as a major neurologic event resulting in a permanent disabling neurologic deficit. Repeat target vessel revascularization was defined as the adjudicated need for a surgical or percutaneous revascularization procedure after the index procedure and within the follow-up period on the basis of recurrence of symptoms or objective evidence of ischemia and confirmed angiographically as renarrowing of the target lesion to >50%.
Statistical analysis Continuous end points were expressed as mean ± SD. Chisquare tests were used to compare count data, and continuous end points were compared with 2-sided unpaired Student t tests. All statistical analyses were performed with SAS software (version 6.12, SAS Institute, Cary, NC).
Results Baseline characteristics Baseline demographic and clinical characteristics are summarized in Table I. The study sample consisted of 70 patients (70 lesions) with a mean age of 60 ± 11 years. Eleven patients (16%) came to the hospital with cardiogenic shock, defined as hypotension requiring pressor or inotropic support. The culprit lesion was located in the left anterior descending (25%), right (45%), left circumflex (9%), and left main (1%) coronary arteries, or saphenous vein graft (20%).
Procedure results and in-hospital outcomes The AngioJet catheter was successfully delivered in all 70 patients (Figure 2). Further mechanical treatment
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Figure 2
A
B
C
D
Acute MI in a patient treated with AngioJet thrombectomy and stenting. A, Initial angiogram shows a discrete lesion and filling defect in the mid–right coronary artery. Approximately 99% of the lumen was occluded. B, The lesion was predilated with a 2-mm balloon; no change in filling defect. C, Three passes were made with the AngioJet catheter, total operating time 115 seconds. D, A small filling defect persisted with residual plaque, which was successfully stented.
Table II. Angiographic results (70 patients, 70 lesions)
TIMI flow (%) 0 1 2 3 Reference vessel diameter (mm) Minimal luminal diameter (mm) % Diameter stenosis Thrombus area (mm2)
Baseline
Post AngioJet
Post final treatment
55.1 8.7 8.7 27.5 3.12 ± 0.62 0.42 ± 0.56 85.8 ± 18.4 73.2 ± 64.6
11.3 8.1 3.2 79.4 3.16 ± 0.61 1.31 ± 0.76 57.7 ± 24.2 15.5 ± 30.1
3.1 0 9.2 87.7 3.18 ± 0.58 2.40 ± 0.75 23.1 ± 21.1 3.2 ± 12.8
after thrombectomy was performed in 95% of the patients: coronary stenting in 67%, balloon angioplasty alone in 26%, rotational atherectomy in 1%, and directional atherectomy in 1%. Four patients required additional intracoronary thrombolytic therapy (urokinase) to further decrease the thrombus burden. Bradycardia induced by operation of the AngioJet catheter occurred in 51.9% of patients, and this was managed with atropine in 3.8%, temporary pacemaker in 17.3%, and combination atropine/pacemaker in 30.7%. Procedural
Statistical significance (baseline vs final) P < .001 P = .034 P = .37 P < .001 P = .82 P < .001 P < .001 P < .001
success was achieved in 93.8% and clinical success in 87.5% of patients. Device success was achieved in 78.0%. The in-hospital mortality rate was 7.1% (5 deaths), and no patients required emergency bypass surgery or had a stroke. Procedural complications included distal embolization in 6 patients (8.6%), transient no reflow in 11 patients (15.7%), sustained slow flow in 2 patients (2.9%), and perforation in 2 patients (2.9%, both successfully sealed by prolonged balloon inflation, without tamponade). Bleeding complications
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Table III. Outcomes by vessel type: saphenous vein grafts and native coronary arteries
Outcome
Saphenous vein graft (n = 14 lesions)
TIMI 3 flow (%) Procedure success (%) Clinical success (%) Postprocedure distal embolization (%) 30-Day mortality (%)
Native coronary artery (n = 56 Statistical lesions) significance
Table IV. Outcomes by use of glycoprotein IIb/IIIa antagonists*
Outcome
+IIb/IIIa use –IIb/IIIa use (17 patients, (48 patients, Statistical 26.2%) 73.8%) significance 88.2 88.2 81.3 0
87.5 95.8 89.6 12.5
P = .99 P = .28 P = .40 P = .33
11.8
5.7
P = .59
71.4 78.6 78.6 7.1
92.2 98.0 90.0 9.8
P = .059 P = .029 P = .357 P = .99
TIMI 3 flow (%) Procedure success (%) Clinical success (%) Postprocedure distal embolization (%) 30-Day mortality (%)
7.1
7.1
P = .99
*Data available for 65 of 70 patients.
occurred in 13 patients (18.6%) and vascular complications occurred in 11 patients (15.7%).
Angiographic results TIMI grade 3 flow was present in 79.4% of the patients after thrombectomy and in 87.7% after final treatment (P < .001 for both postthrombectomy and final vs baseline) (Table II). Final TIMI 2 or 3 flow was achieved in 96.9%. There were four instances in which TIMI 3 flow after thrombectomy was reduced to TIMI 2 flow after final treatment (7.4%). The final treatment in these cases was stenting in three and balloon angioplasty in one. The MLD increased from 0.42 ± 0.56 mm before the procedure to 1.31 ± 0.76 mm after thrombectomy and to 2.4 ± 0.75 mm after final treatment. Thrombus burden was reduced from 73.2 ± 64.6 mm2 at baseline to 15.5 ± 30.1 mm2 after thrombectomy and to 3.2 ± 12.8 mm2 after final treatment (P < .001 for both postthrombectomy and final vs baseline).
30-Day clinical outcome After discharge from the hospital, there were no additional deaths, strokes, recurrent MIs, or need for repeat percutaneous or surgical target vessel revascularization by 30-day follow-up. The overall 30-day freedom from major adverse cardiac event rate was 92.9% (65 of 70 patients). A comparison of outcomes of patients undergoing saphenous vein graft intervention with those undergoing native coronary artery intervention is shown in Table III. The procedure success rate and TIMI 3 flow rate were higher in native coronary arteries. There were no significant differences in outcomes of patients who received IIb/IIIa antagonists compared with those who did not receive this treatment (Table IV).
Discussion The current study showed that AngioJet treatment successfully removed angiographically evident intracoronary/graft thrombus (net thrombus area reduction of 57.7 mm2), resulting in final TIMI 3 flow in the
majority of patients (87.8%). Our series of 70 patients represents a severely ill, high-risk subset of patients with acute MI: 16% had cardiogenic shock, the mean baseline ejection fraction was 44%, 37% had prior MI, and the culprit thrombus lesion was located in a saphenous vein graft or the left main coronary artery in 21%. An acceptable overall 1-month mortality rate of 7.1% (5 in-hospital deaths) was achieved, and rates of distal embolization (8.6%) and sustained slow flow (2.9%) were also relatively low, despite intervention in the setting of extensive angiographically evident thrombus. The incidence of perforation was 2.9%. The perforation rate was 1.1% in the VeGAS 1 pilot study (n = 90 patients) and 1.7% in the VeGAS pivotal randomized trial (n = 350 patients).18,20 In each of these cases, we were not able to determine the specific role of the AngioJet catheter in the mechanism of perforation because the perforation was evident only after the final definitive stenting procedure. However, the potential for final treatment to cause perforation in these patients was underscored by the 1.2% perforation rate seen in the control arm of the VeGAS 2 trial. To avoid possible injury, it is recommended that the AngioJet catheter not be used in vessels less than 2.0 mm, and we have found that no other lesion or vessel characteristics were predictive of complications (using all available data from the trials). Because prior studies have not explicitly addressed the treatment of acute MI patients with overt intracoronary thrombus, direct comparison with our results is difficult. Our study, however, demonstrated a final TIMI 3 grade flow in 87.7% of patients, which is higher than the 73% rate seen in the Global Use of Strategies To Open Occluded Coronary Arteries in Acute Coronary Syndromes (GUSTO IIb) study2 but lower than the 96% rate achieved in the Primary Angioplasty in Myocardial Infarction (PAMI) Stent Trial.21 We observed no incidence of recurrent ischemia, infarction, or revacularization at 30 days, which compares favorably with the 9% to 15% recurrent ischemia rate seen in the other studies and the 3.8% reinfarction rate
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and 3% two-vessel revascularization rate seen in the PAMI Stent Trial.2,21-24 An important distinction between our study and these prospective primary percutaneous transluminal coronary angioplasty (PTCA)/stent trials is that cardiogenic shock, prior stroke, and culprit lesions located in the left main artery or a vein graft were excluded in the other trials. Compared with patients who were enrolled in the primary PTCA trials, the mortality rate is up to five times greater for patients who have clinical factors that exclude them from these trials.25 In a recent series of stenting in patients with acute MI complicated by cardiogenic shock, the 6-month mortality rate was 27%, with all deaths occurring in the initial 30 days.26 Results from the randomized Should We Emergently Revascularize Occluded Coronaries for Cardiogenic Shock (SHOCK) trial (to evaluate early revascularization in acute MI complicated by cardiogenic shock) showed a 30-day mortality rate of 46.7% and a 6-month mortality rate of 50.3%, which was significantly lower compared with rates observed for patients treated with medical stabilization only.27 Other percutaneous strategies for the treatment of thrombus-containing lesions in acute MI include mechanical compression by balloon angioplasty or stenting and catheter-based interventions using transluminal extraction atherectomy (TEC) or intravascular ultrasonographic thrombolysis. The TEC device macerates atherosclerotic plaque and coronary thrombi by the interaction of a rotating cutter and a continuous vacuum suction.17 TEC has been shown to be effective in the treatment of native coronary artery and saphenous vein graft disease complicated by thrombus, although distal embolization occasionally occurs. In a prospective evaluation of 100 patients with acute MI undergoing TEC treatment, procedure success was achieved in 94%, TIMI 3 flow was achieved in 65%, but thrombus removal was not quantified.28 Intravascular ultrasonic thrombolysis (Acolysis System, Angiosonics, Morrisville, NC) applies low-frequency ultrasound for rapid mechanical thrombolysis. The initial results of ultrasonic thrombolysis in 15 patients with acute anterior MI showed successful TIMI 3 reperfusion in 87%, with a low in-hospital complication rate.29 Primary stenting in acute MI has been shown to reduce the need for repeat interventions.24,30 Restoration of high coronary flow rates usually suffices to overcome the prothrombotic tendencies of the freshly placed stent exposed to the intravascular pool of activated platelets seen with acute MI. However, when stents are placed in emergency situations or as bail-out devices after nonstent procedures, the rate of stent thrombosis may be substantial, especially in the presence of a large thrombus burden.31 AngioJet has also been used successfully in the treatment of acute/subacute coronary stent thrombosis.32 In the setting of
acute MI, stenting may result in a decline in coronary flow, and the incidence of reduced TIMI flow by stenting or balloon angioplasty was 7.4% in our study. These results are consistent with those observed in the PAMI stent trial and we therefore provide no evidence that AngioJet thrombectomy reduces the problem of occasional reduced flow after stenting.24 The use of IIb/IIIa antagonists has been shown to decrease procedural complication rates in patients with acute coronary ischemia undergoing balloon angioplasty or stenting; however, the incremental benefit that these agents add to stenting has not been established.15,16,33 IIb/IIIa antagonists were used in a minority of patients in our study, and no significant additional benefit was demonstrated (Table IV); however, our study was not designed to evaluate combined treatment of IIb/IIIa antagonists with AngioJet thrombectomy.
Limitations Because of the exploratory nature of our study, we did not attempt to demonstrate the incremental benefit of AngioJet thrombectomy in the MI setting, by comparison with alternative methods of revascularization. Therefore we cannot determine the true clinical utility of this device compared with other strategies for the treatment of acute MI complicated by angiographically evident thrombus. Nevertheless, the degree of thrombus resolution in the current study was impressive, and the relatively low incidence of complications suggests that direct thrombus removal may play an important role in the treatment of acute MI in select patients.
References 1. Global Use of Strategies to Open Occluded Coronary Arteries (GUSTO) Angiographic Investigators. The effect of tissue plasminogen activator, streptokinase, or both on coronary artery patency, ventricular function, and survival after acute myocardial infarction. N Engl J Med 1993;329:1615-22. 2. Global Use of Strategies to Open Occluded Coronary Arteries in Acute Coronary Syndromes (GUSTO) IIb Angioplasty Substudy Investigators. A clinical trial comparing primary coronary angioplasty with tissue plasminogen activator for acute myocardial infarction. N Engl J Med 1997;336:1621-8. 3. Ryan TJ, Ryan TJ Jr, Jacobs AK. Primary PTCA versus thrombolytic therapy: an evidence-based summary. Am Heart J 1999;138 (Suppl):S96-104. 4. Stone GW, Grines CL, Browne KF, et al. Implications of recurrent ischemia after reperfusion therapy in acute myocardial infarction: a comparison of thrombolytic therapy and primary angioplasty. J Am Coll Cardiol 1995;26:66-72. 5. White CJ, Ramee SR, Collins TJ, et al. Coronary thrombi increase PTCA risk: angioscopy as a clinical tool. Circulation 1996;93: 253-8. 6. Mabin T, Holmes DR Jr, Smith HC, et al. Intracoronary thrombus: role in coronary occlusion complicating percutaneous transluminal coronary angioplasty. J Am Coll Cardiol 1985;5:198-202. 7. Khan MM, Ellis SG, Aguirre FV, et al. Does intracoronary thrombus
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influence the outcome of high risk percutaneous transluminal coronary angioplasty? J Am Coll Cardiol 1998;31:31-6. Violaris AG, Melkert R, Hermann JP, et al. Role of angiographically identifiable thrombus on long-term luminal renarrowing after coronary angioplasty: a quantitative angiographic analysis. Circulation 1996;93:889-97. Bauters C, Lablanche JM, McFadden EP, et al. Relation of coronary angioscopic findings at coronary angioplasty to angiographic restenosis. Circulation 1995;92:2473-9. Simoons ML, Arnold AE, Betriu A, et al. Thrombolysis with tissue plasminogen activator in acute myocardial infarction: no additional benefit from immediate percutaneous coronary angioplasty. Lancet 1988;1:197-203. Ambrose JA, Almeida OD, Sharma SK, et al. Adjunctive thrombolytic therapy during angioplasty for ischemic rest angina. Results of the TAUSA trial. TAUSA investigators. Thrombolysis and Angioplasty in Unstable Angina Trial. Circulation 1994;90:69-77. Baim DS, Diver DJ, Feit F, et al. Coronary angioplasty performed within the thrombolysis in myocardial infarction II study. Circulation 1992;85:93-105. Ross AM, Coyne KS, Reiner JS, et al. A randomized trial comparing primary angioplasty with a strategy of short-acting thrombolysis and immediate planned rescue angioplasty in acute myocardial infarction: the PACT trial. J Am Coll Cardiol 1999;34:1954-62. Brener SJ, Barr LA, Burchenal JB, et al. Randomized, placebocontrolled trial of platelet glycoprotein IIb/IIIa blockade with primary angioplasty for acute myocardial infarction: ReoPro and Primary PTCA Organization and Randomized Trial (RAPPORT) Investigators. Circulation 1998;98:734-41. EPIC Investigators. Use of monoclonal antibody directed against the platelet glycoprotein IIb/IIIa receptor in high-risk coronary angioplasty. N Engl J Med 1994;330:956-61. EPILOG Investigators. Platelet glycoprotein IIb/IIIa receptor blockade and low-dose heparin during percutaneous coronary revascularization. N Engl J Med 1997;336:1689-96. Safian RD, May MA, Lichtenberg A, et al. Detailed clinical and angiographic analysis of transluminal extraction coronary atherectomy for complex lesions in native coronary arteries. J Am Coll Cardiol 1995;25:848-54. Ramee SR, Kuntz RE, Schatz RA, et al. Preliminary experience with the POSSIS coronary AngioJet rheolytic thrombectomy catheter in the VeGAS 1 pilot study [abstract]. J Am Coll Cardiol 1996;69A. Whisenant BK, Baim DS, Kuntz RE, et al. Rheolytic thrombectomy with the Possis AngioJet: technical considerations and initial clinical experience. J Invasiv Cardiol 1999;11:421-6. Ramee SR, Baim DS, Popma JJ, et al. A randomized prospective multicenter study comparing intracoronary urokinase to rheolytic
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thrombectomy with the Possis AngioJet catheter for intracoronary thrombus: final results of the VeGAS 2 trial [abstract]. Circulation 1998;98:I86. Grines CL, Browne KF, Marco J, et al. A comparison of immediate angioplasty with thrombolytic therapy for acute myocardial infarction: the Primary Angioplasty in Myocardial Infarction Study Group. N Engl J Med 1993;328:673-9. Ziljistra F, DeBoer MJ, Hoorntje JC, et al. A comparison of immediate coronary angioplasty with intravenous streptokinase in acute myocardial infarction. N Engl J Med 1993;328:680-4. Gibbons RJ, Holmes DR, Reeder GS, et al. Immediate angioplasty compared with the administration of a thrombolytic agent followed by conservative treatment for myocardial infarction: the Mayo Coronary Care Unit and Catheterization Laboratory Groups. N Engl J Med 1993;328:685-91. Grines CL, Cox DA, Stone GW, et al. Coronary angioplasty with or without stent implantation for acute myocardial infarction. N Engl J Med 1999;341:1949-56. Dauerman HL, Pinto DS, Ho KKL, et al. Acute infarct angioplasty: differential mortality of trial-eligible and ineligible patients. Cathet Cardiovasc Interven 2000. In press. Webb JG, Carere RG, Hilton JD, et al. Usefulness of coronary stenting for cardiogenic shock. Am J Cardiol 1997;79:81-4. Hochman JS, Sleeper LA, Webb JG, et al. Early revascularization in acute myocardial infarction complicated by cardiogenic shock. N Engl J Med 1999;341:625-34. Kaplan BM, Larkin T, Safian RD, et al. Prospective study of extraction atherectomy in patients with acute myocardial infarction. Am J Cardiol 1996;78:383-8. Rosenschein U, Roth A, Rassin T, et al. Analysis of coronary ultrasound thrombolysis endpoints in acute myocardial infarction (ACUTE Trial): results of the feasibility study. Circulation 1997;95: 1411-6. Antoniucci D, Santoro GM, Bolognese L, et al. A clinical trial comparing primary stenting of infarct-related artery with optimal primary angioplasty for acute myocardial infarction: results from the Florence Randomized Elective Stenting in Acute Coronary Occlusions (FRESCO) trial. J Am Coll Cardiol 1998;31:1234-9. Stone G. Stenting in acute myocardial infarction: observational studies and randomized trials. J Invasiv Cardiol 1998;10:16-26A. Scott LR, Silva JA, White C et al. Rheolytic thrombectomy: a new treatment for stent thrombosis. Cathet Cardiovasc Intervent 1999; 47:97-101. Keriakes DJ, Lincoff AM, Miller DP et al. Abciximab therapy and unplanned coronary stenting: favorable effect on stent use, clinical outcomes, and bleeding complications. Circulation 1998;97:85764.
Background Although balloon angioplasty and stenting are effective in the treatment of acute myocardial infarction (MI), reduced coronary flow and distal embolization frequently complicate interventions when thrombus is present. Adjunctive treatment with mechanical thrombectomy devices may reduce these complications.
Methods and Results We evaluated the angiographic and clinical outcomes of 70 patients with acute MI (16% with cardiogenic shock) and with angiographically evident thrombus who were treated with AngioJet rheolytic thrombectomy followed by immediate definitive treatment. Procedure success (residual diameter stenosis <50% and Thrombolysis in Myocardial Infarction [TIMI] flow ≥2 after final treatment) was achieved in 93.8%. Clinical success (procedure success without major in-hospital cardiac events) was achieved in 87.5%, with an in-hospital mortality rate of 7.1%. Final TIMI 3 flow was achieved in 87.7%. AngioJet treatment resulted in a mean thrombus area reduction from 73.2 ± 64.6 mm2 at baseline to 15.5 ± 30.1 post-thrombectomy (P < .001). Subsequent definitive treatment included stenting in 67% and balloon angioplasty alone in 26% of patients. Procedural complications included distal embolization in six patients and perforation in two patients. There were no further major adverse events during 30-day follow-up. Conclusion Rheolytic thrombectomy can be performed safely and effectively in patients with acute MI, allowing for immediate definitive treatment in thrombus-containing lesions. (Am Heart J 2001;141:353-9.)
Sudden thrombotic occlusion is responsible for acute myocardial infarction (MI) in the majority of patients, and rapid restoration of normal coronary flow preserves myocardial function and improves long-term prognosis.1 Early reperfusion can be accomplished with pharmacologic thrombolysis or primary percutaneous angioplasty. Primary angioplasty has been shown to provide higher rates of Thrombolysis in Myocardial Infarction (TIMI) 3 coronary flow and preservation of left ventricular function compared with pharmacologic thrombolysis but is limited by higher rates of reocclusion, recurrent infarction, and restenosis compared with elective angioplasty.2-4 The presence of thrombus in acute MI may be From the aAlton Ochsner Medical Foundation, New Orleans, La, bBeth Israel Deaconess Medical Center and cBrigham and Women’s Hospital, Boston, Mass, dLenox Hill Hospital, New York, NY, eMid-Ohio Cardiology Consultants, Columbus, Ohio, the fCardiology Consultants of Philadelphia, Philadelphia, Pa, and gPossis Medical, Minneapolis, Minn. Submitted March 16, 2000; accepted November 17, 2000. Reprint requests: Richard E. Kuntz, MD, MSc, Cardiovascular Division, Brigham and Women’s Hospital, 75 Francis St, Boston, MA 02215. E-mail: [email protected] Copyright © 2001 by Mosby, Inc. 0002-8703/2001/$35.00 + 0 4/1/112997 doi:10.1067/mhj.2001.112997
a major factor responsible for the development of these complications.5-9 Although thrombus removal before definitive catheter-based intervention in acute MI may be desirable, antecedent or adjunctive pharmacologic thrombolysis has not been shown to improve the clinical outcomes of coronary intervention.10-12 Strategies using combined reduced-dose thrombolysis and subsequent intervention, however, show promise.13 The use of glycoprotein IIb/IIIa receptor antagonists as an adjunctive pharmacologic regimen to direct angioplasty has been shown to reduce the need for urgent repeat interventions.14-16 Mechanical removal of thrombus with transluminal extraction atherectomy (TEC catheter, Interventional Technologies, San Diego, Calif) may obviate the problems of systemic thrombolysis, but treatment is associated with suboptimal outcomes in thrombuscontaining lesions.17 AngioJet rheolytic thrombectomy (Possis Medical, Minneapolis, Minn) is a catheter-based method for thrombus removal. High-velocity saline solution jets are used to create a localized low-pressure zone at the distal catheter tip (Bernoulli effect), which results in the maceration and removal of thrombus through an exhaust
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Figure 1
AngioJet LF140 rheolytic thrombectomy catheter, distal tip.
lumen. The use of rheolytic thrombectomy in the treatment of non-MI thrombus-containing coronary lesions has been previously reported.18-20 The purpose of the current study was to assess the safety and clinical efficacy of adjunctive rheolytic thrombectomy during percutaneous revascularization for acute MI.
a mobile or fixed intraluminal filling defect outlined or stained by contrast dye; and target lesion with at least 70% diameter stenosis. Patients were excluded if they had received thrombolytic therapy within 24 hours of the intended AngioJet procedure.
Methods
On arrival to the emergency department, patients received a chewable aspirin (325 mg) along with standard medical treatment for acute MI (intravenous β-blockers, nitrates, etc), at the emergency physician’s discretion. After the diagnosis of acute MI was confirmed and informed consent was obtained, the patient was taken to the cardiac catheterization laboratory for emergency mechanical intervention. Intravenous heparin was given to maintain an activated clotting time of >250 seconds. Platelet IIb/IIIa antagonists were used in 26.2% of patients. The AngioJet LF140 rheolytic catheter is a 5F, dual-lumen, over-the-wire design, as described previously.19 Multiple highvelocity saline solution jets create a localized low-pressure zone at the catheter distal tip (Bernoulli effect), which results in the maceration and removal of thrombus through the effluent lumen (Figure 1). An external piston pump console provides the pressurized pulsatile flow that supplies the jets. After angiographic confirmation of the presence of thrombus, an 8F or 9F guiding catheter was placed in the target vessel, followed by advancement of a 0.014- or 0.018-inch guide wire into the distal vessel. Because transient bradyarrhythmias may occur during rheolytic thrombectomy, a temporary pacing wire was generally placed before treatment. The thrombectomy catheter was then connected to the pump console, flushed, and advanced through the guiding catheter over the guide wire. The pump console was activated by depressing a foot switch, and the catheter was passed slowly across the thrombosed segment in either a distal-to-proximal or proximal-to-distal direction, at a rate of 1 to 2 mm per second. Angiography was obtained after each pass, and additional
Patient population The study population included 70 consecutive patients who had a transmural acute MI within 8 hours of symptom onset and who were enrolled in the Food and Drug Administration (FDA)–approved Vein Graft AngioJet Study-1 (VeGAS 1) or VeGAS 2 acute MI Registry. The protocols were approved by the Institutional Review Boards at each site. Sixteen patients were drawn from VeGAS 1, a 90-patient pilot registry of AngioJet thrombectomy in thrombus-containing saphenous vein bypass grafts and native coronary arteries.18 The remaining 54 patients were drawn from the VeGAS 2 Acute MI Registry, which included 90 patients with angiographic thrombus, treated with AngioJet during an acute MI, and who were seen within 24 hours of symptom onset. Only those patients who were seen within 8 hours of symptom onset were included in the current analysis. Patients analyzed in the current study were identified by a Clinical Events Committee, blinded to the goals of the study, on the basis of evidence of acute MI and symptom onset within 8 hours of intervention. Acute MI was defined as the presence of at least two of the following three criteria: ongoing ischemic pain, ≥0.1 mm ST elevation in two contiguous electrocardiogram (ECG) leads, and elevation of cardiac enzymes to at least two times the upper limit of normal. Patients were also required to meet all the following angiographic inclusion criteria: target lesion reference diameter of at least 2.0 mm; angiographically evident thrombus, defined as
Patient treatment
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passes were performed until all filling defects had been removed or there was no further improvement between passes. In most cases, adjunctive balloon angioplasty or stenting was performed after thrombectomy, with use of standard techniques. Stent sizing was based on a balloon-to-artery ratio of 1.1:1 and inflation pressures of 10 to 20 atmospheres to attain <10% residual stenosis by visual estimate. After final balloon angioplasty or stenting, anticoagulant and antiplatelet therapy included various combinations of aspirin (325 mg daily), ticlopidine (250 mg twice daily for 4 weeks), coumadin (titrated to international normalized ratio of 2.0-2.5), and intravenous heparin for 24 to 48 hours.
Data collection Clinical data were obtained by study coordinators using standardized case report forms, were independently monitored, and were submitted to the data coordinating center (CDAC, Harvard Medical School, Boston, Mass). ECGs were reviewed by the Electrocardiographic Core Laboratory (CDAC, Boston, Mass) blinded to clinical events. Procedural angiograms were submitted to the Angiographic Core Laboratory (Washington Hospital Center, Washington, DC) and analyzed with the CAAS2 system (Pie Medical, Maastricht, The Netherlands). Clinical follow-up was obtained at hospital discharge and at 4 weeks after the index procedure. All events were adjudicated by an independent Clinical Events Committee.
Angiography Cineangiograms of the target lesion were acquired in two angiographic projections before and after thrombectomy treatment and after final treatment. Intracoronary nitroglycerin (50-200 µg) was recommended before angiography, unless contraindicated. The mean reference vessel diameter, minimal lumen diameter (MLD), percent diameter stenosis, and thrombus area were calculated from an average of the two angiographic projections with use of an automated edge detection algorithm (CAAS2). Thrombus area was determined before and after thrombectomy and after final treatment by dividing the vessel in multiple equal segments and calculating the axial length and width of radiolucency in each segment.
End points Procedure success was defined as attainment of TIMI grade 2 or 3 coronary flow and residual diameter stenosis <50% by use of any percutaneous method. The primary end point in this study was clinical success, defined as procedural success without death, major disabling stroke, or emergency bypass surgery during the index hospital stay. Device success was defined as the restoration of TIMI 3 coronary flow and attainment of <50% diameter stenosis after thrombectomy treatment only. Secondary end points included 30-day major adverse cardiovascular events (death, reinfarction, target vessel revascularization) and procedural complications, including perforation, sustained slow flow, distal embolization, bleeding complications, and vascular complications. Sustained slow flow was defined as the occurrence of sudden reduced coronary flow to
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Table I. Baseline demographic and clinical characteristics Characteristic Age (mean ± SD) No. of men Hypertension Dyslipidemia Tobacco use Diabetes mellitus Prior MI Prior coronary artery bypass graft LV ejection fraction (mean ± SD) Duration of chest pain (mean ± SD) Extent of coronary disease 1 vessel 2 vessel 3 vessel Cardiogenic shock Peak creatine kinase (mean ± SD)
N = 70 patients, 70 lesions 60 ± 11 years 66% 48% 24% 42% 19% 37% 22% 44% ± 10% 3.7 ± 1.9 hours 56% 26% 19% 16% 2829 ± 2861 IU/mL
branches or a new abrupt cutoff of distal vessels and branches (by Angiographic Core Lab assessment). Bleeding complications consisted of procedure-related blood transfusions. Vascular complications were defined as the occurrence of hematoma >4 cm, retroperitoneal bleed, false aneurysm, atrioventricular fistula, peripheral ischemia/nerve injury, hemolysis, or hemolytic anemia. Major disabling stroke was defined as a major neurologic event resulting in a permanent disabling neurologic deficit. Repeat target vessel revascularization was defined as the adjudicated need for a surgical or percutaneous revascularization procedure after the index procedure and within the follow-up period on the basis of recurrence of symptoms or objective evidence of ischemia and confirmed angiographically as renarrowing of the target lesion to >50%.
Statistical analysis Continuous end points were expressed as mean ± SD. Chisquare tests were used to compare count data, and continuous end points were compared with 2-sided unpaired Student t tests. All statistical analyses were performed with SAS software (version 6.12, SAS Institute, Cary, NC).
Results Baseline characteristics Baseline demographic and clinical characteristics are summarized in Table I. The study sample consisted of 70 patients (70 lesions) with a mean age of 60 ± 11 years. Eleven patients (16%) came to the hospital with cardiogenic shock, defined as hypotension requiring pressor or inotropic support. The culprit lesion was located in the left anterior descending (25%), right (45%), left circumflex (9%), and left main (1%) coronary arteries, or saphenous vein graft (20%).
Procedure results and in-hospital outcomes The AngioJet catheter was successfully delivered in all 70 patients (Figure 2). Further mechanical treatment
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Figure 2
A
B
C
D
Acute MI in a patient treated with AngioJet thrombectomy and stenting. A, Initial angiogram shows a discrete lesion and filling defect in the mid–right coronary artery. Approximately 99% of the lumen was occluded. B, The lesion was predilated with a 2-mm balloon; no change in filling defect. C, Three passes were made with the AngioJet catheter, total operating time 115 seconds. D, A small filling defect persisted with residual plaque, which was successfully stented.
Table II. Angiographic results (70 patients, 70 lesions)
TIMI flow (%) 0 1 2 3 Reference vessel diameter (mm) Minimal luminal diameter (mm) % Diameter stenosis Thrombus area (mm2)
Baseline
Post AngioJet
Post final treatment
55.1 8.7 8.7 27.5 3.12 ± 0.62 0.42 ± 0.56 85.8 ± 18.4 73.2 ± 64.6
11.3 8.1 3.2 79.4 3.16 ± 0.61 1.31 ± 0.76 57.7 ± 24.2 15.5 ± 30.1
3.1 0 9.2 87.7 3.18 ± 0.58 2.40 ± 0.75 23.1 ± 21.1 3.2 ± 12.8
after thrombectomy was performed in 95% of the patients: coronary stenting in 67%, balloon angioplasty alone in 26%, rotational atherectomy in 1%, and directional atherectomy in 1%. Four patients required additional intracoronary thrombolytic therapy (urokinase) to further decrease the thrombus burden. Bradycardia induced by operation of the AngioJet catheter occurred in 51.9% of patients, and this was managed with atropine in 3.8%, temporary pacemaker in 17.3%, and combination atropine/pacemaker in 30.7%. Procedural
Statistical significance (baseline vs final) P < .001 P = .034 P = .37 P < .001 P = .82 P < .001 P < .001 P < .001
success was achieved in 93.8% and clinical success in 87.5% of patients. Device success was achieved in 78.0%. The in-hospital mortality rate was 7.1% (5 deaths), and no patients required emergency bypass surgery or had a stroke. Procedural complications included distal embolization in 6 patients (8.6%), transient no reflow in 11 patients (15.7%), sustained slow flow in 2 patients (2.9%), and perforation in 2 patients (2.9%, both successfully sealed by prolonged balloon inflation, without tamponade). Bleeding complications
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Table III. Outcomes by vessel type: saphenous vein grafts and native coronary arteries
Outcome
Saphenous vein graft (n = 14 lesions)
TIMI 3 flow (%) Procedure success (%) Clinical success (%) Postprocedure distal embolization (%) 30-Day mortality (%)
Native coronary artery (n = 56 Statistical lesions) significance
Table IV. Outcomes by use of glycoprotein IIb/IIIa antagonists*
Outcome
+IIb/IIIa use –IIb/IIIa use (17 patients, (48 patients, Statistical 26.2%) 73.8%) significance 88.2 88.2 81.3 0
87.5 95.8 89.6 12.5
P = .99 P = .28 P = .40 P = .33
11.8
5.7
P = .59
71.4 78.6 78.6 7.1
92.2 98.0 90.0 9.8
P = .059 P = .029 P = .357 P = .99
TIMI 3 flow (%) Procedure success (%) Clinical success (%) Postprocedure distal embolization (%) 30-Day mortality (%)
7.1
7.1
P = .99
*Data available for 65 of 70 patients.
occurred in 13 patients (18.6%) and vascular complications occurred in 11 patients (15.7%).
Angiographic results TIMI grade 3 flow was present in 79.4% of the patients after thrombectomy and in 87.7% after final treatment (P < .001 for both postthrombectomy and final vs baseline) (Table II). Final TIMI 2 or 3 flow was achieved in 96.9%. There were four instances in which TIMI 3 flow after thrombectomy was reduced to TIMI 2 flow after final treatment (7.4%). The final treatment in these cases was stenting in three and balloon angioplasty in one. The MLD increased from 0.42 ± 0.56 mm before the procedure to 1.31 ± 0.76 mm after thrombectomy and to 2.4 ± 0.75 mm after final treatment. Thrombus burden was reduced from 73.2 ± 64.6 mm2 at baseline to 15.5 ± 30.1 mm2 after thrombectomy and to 3.2 ± 12.8 mm2 after final treatment (P < .001 for both postthrombectomy and final vs baseline).
30-Day clinical outcome After discharge from the hospital, there were no additional deaths, strokes, recurrent MIs, or need for repeat percutaneous or surgical target vessel revascularization by 30-day follow-up. The overall 30-day freedom from major adverse cardiac event rate was 92.9% (65 of 70 patients). A comparison of outcomes of patients undergoing saphenous vein graft intervention with those undergoing native coronary artery intervention is shown in Table III. The procedure success rate and TIMI 3 flow rate were higher in native coronary arteries. There were no significant differences in outcomes of patients who received IIb/IIIa antagonists compared with those who did not receive this treatment (Table IV).
Discussion The current study showed that AngioJet treatment successfully removed angiographically evident intracoronary/graft thrombus (net thrombus area reduction of 57.7 mm2), resulting in final TIMI 3 flow in the
majority of patients (87.8%). Our series of 70 patients represents a severely ill, high-risk subset of patients with acute MI: 16% had cardiogenic shock, the mean baseline ejection fraction was 44%, 37% had prior MI, and the culprit thrombus lesion was located in a saphenous vein graft or the left main coronary artery in 21%. An acceptable overall 1-month mortality rate of 7.1% (5 in-hospital deaths) was achieved, and rates of distal embolization (8.6%) and sustained slow flow (2.9%) were also relatively low, despite intervention in the setting of extensive angiographically evident thrombus. The incidence of perforation was 2.9%. The perforation rate was 1.1% in the VeGAS 1 pilot study (n = 90 patients) and 1.7% in the VeGAS pivotal randomized trial (n = 350 patients).18,20 In each of these cases, we were not able to determine the specific role of the AngioJet catheter in the mechanism of perforation because the perforation was evident only after the final definitive stenting procedure. However, the potential for final treatment to cause perforation in these patients was underscored by the 1.2% perforation rate seen in the control arm of the VeGAS 2 trial. To avoid possible injury, it is recommended that the AngioJet catheter not be used in vessels less than 2.0 mm, and we have found that no other lesion or vessel characteristics were predictive of complications (using all available data from the trials). Because prior studies have not explicitly addressed the treatment of acute MI patients with overt intracoronary thrombus, direct comparison with our results is difficult. Our study, however, demonstrated a final TIMI 3 grade flow in 87.7% of patients, which is higher than the 73% rate seen in the Global Use of Strategies To Open Occluded Coronary Arteries in Acute Coronary Syndromes (GUSTO IIb) study2 but lower than the 96% rate achieved in the Primary Angioplasty in Myocardial Infarction (PAMI) Stent Trial.21 We observed no incidence of recurrent ischemia, infarction, or revacularization at 30 days, which compares favorably with the 9% to 15% recurrent ischemia rate seen in the other studies and the 3.8% reinfarction rate
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and 3% two-vessel revascularization rate seen in the PAMI Stent Trial.2,21-24 An important distinction between our study and these prospective primary percutaneous transluminal coronary angioplasty (PTCA)/stent trials is that cardiogenic shock, prior stroke, and culprit lesions located in the left main artery or a vein graft were excluded in the other trials. Compared with patients who were enrolled in the primary PTCA trials, the mortality rate is up to five times greater for patients who have clinical factors that exclude them from these trials.25 In a recent series of stenting in patients with acute MI complicated by cardiogenic shock, the 6-month mortality rate was 27%, with all deaths occurring in the initial 30 days.26 Results from the randomized Should We Emergently Revascularize Occluded Coronaries for Cardiogenic Shock (SHOCK) trial (to evaluate early revascularization in acute MI complicated by cardiogenic shock) showed a 30-day mortality rate of 46.7% and a 6-month mortality rate of 50.3%, which was significantly lower compared with rates observed for patients treated with medical stabilization only.27 Other percutaneous strategies for the treatment of thrombus-containing lesions in acute MI include mechanical compression by balloon angioplasty or stenting and catheter-based interventions using transluminal extraction atherectomy (TEC) or intravascular ultrasonographic thrombolysis. The TEC device macerates atherosclerotic plaque and coronary thrombi by the interaction of a rotating cutter and a continuous vacuum suction.17 TEC has been shown to be effective in the treatment of native coronary artery and saphenous vein graft disease complicated by thrombus, although distal embolization occasionally occurs. In a prospective evaluation of 100 patients with acute MI undergoing TEC treatment, procedure success was achieved in 94%, TIMI 3 flow was achieved in 65%, but thrombus removal was not quantified.28 Intravascular ultrasonic thrombolysis (Acolysis System, Angiosonics, Morrisville, NC) applies low-frequency ultrasound for rapid mechanical thrombolysis. The initial results of ultrasonic thrombolysis in 15 patients with acute anterior MI showed successful TIMI 3 reperfusion in 87%, with a low in-hospital complication rate.29 Primary stenting in acute MI has been shown to reduce the need for repeat interventions.24,30 Restoration of high coronary flow rates usually suffices to overcome the prothrombotic tendencies of the freshly placed stent exposed to the intravascular pool of activated platelets seen with acute MI. However, when stents are placed in emergency situations or as bail-out devices after nonstent procedures, the rate of stent thrombosis may be substantial, especially in the presence of a large thrombus burden.31 AngioJet has also been used successfully in the treatment of acute/subacute coronary stent thrombosis.32 In the setting of
acute MI, stenting may result in a decline in coronary flow, and the incidence of reduced TIMI flow by stenting or balloon angioplasty was 7.4% in our study. These results are consistent with those observed in the PAMI stent trial and we therefore provide no evidence that AngioJet thrombectomy reduces the problem of occasional reduced flow after stenting.24 The use of IIb/IIIa antagonists has been shown to decrease procedural complication rates in patients with acute coronary ischemia undergoing balloon angioplasty or stenting; however, the incremental benefit that these agents add to stenting has not been established.15,16,33 IIb/IIIa antagonists were used in a minority of patients in our study, and no significant additional benefit was demonstrated (Table IV); however, our study was not designed to evaluate combined treatment of IIb/IIIa antagonists with AngioJet thrombectomy.
Limitations Because of the exploratory nature of our study, we did not attempt to demonstrate the incremental benefit of AngioJet thrombectomy in the MI setting, by comparison with alternative methods of revascularization. Therefore we cannot determine the true clinical utility of this device compared with other strategies for the treatment of acute MI complicated by angiographically evident thrombus. Nevertheless, the degree of thrombus resolution in the current study was impressive, and the relatively low incidence of complications suggests that direct thrombus removal may play an important role in the treatment of acute MI in select patients.
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