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Risk of Acute Kidney Injury after Percutaneous Pharmacomechanical Thrombectomy Using AngioJet in Venous and Arterial Thrombosis
Accepted Manuscript Risk of acute kidney injury after percutaneous pharmacomechanical thrombectomy using Angiojet in venous and arterial thrombosis Guillermo A. Escobar, MD, Dillon Burks, BS, Matthew R. Abate, MD, Mohammed F. Faramawi, MD, Ahsan T. Ali, MD, Lewis C. Lyons, MD, Mohammed M. Moursi, MD, Matthew R. Smeds, MD PII:
S0890-5096(17)30646-5
DOI:
10.1016/j.avsg.2016.12.018
Reference:
AVSG 3263
To appear in:
Annals of Vascular Surgery
Received Date: 15 April 2016 Revised Date:
8 July 2016
Accepted Date: 5 December 2016
Please cite this article as: Escobar GA, Burks D, Abate MR, Faramawi MF, Ali AT, Lyons LC, Moursi MM, Smeds MR, Risk of acute kidney injury after percutaneous pharmacomechanical thrombectomy using Angiojet in venous and arterial thrombosis, Annals of Vascular Surgery (2017), doi: 10.1016/ j.avsg.2016.12.018. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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1 2 3 Risk of acute kidney injury after percutaneous pharmacomechanical thrombectomy using
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Angiojet in venous and arterial thrombosis
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Guillermo A. Escobar, MD, Dillon Burks, BS, Matthew R. Abate, MD, Mohammed F.
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Faramawi, MD, Ahsan T. Ali, MD, Lewis C. Lyons MD, Mohammed M. Moursi MD, and
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Matthew R. Smeds, MD
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Corresponding Author:
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Assistant Professor of Surgery, Vascular Surgery Division
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Guillermo A Escobar, MD
University of Arkansas for Medical Sciences
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4301 W Markham St. #520-2 Little Rock, AR 72205-7199
Phone (501) 686-6176, Fax (501) 686-5328 [email protected]
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24 Disclosures
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No author has a conflict of interest related to this research, and no external funding was obtained
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to obtain or analyze this data.
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Abstract
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Background: Percutaneous mechanical thrombectomy (PMT) is commonly used to treat acute
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thrombotic syndromes. Angiojet (AJ) forcibly sprays fibrinolytics to fragment and aspirate
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thrombus. It’s known to cause hemolysis and gross hematuria, yet potential consequences to
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renal function after AJ remain unstudied. We sought to determine the risk of acute kidney injury
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(AKI) after AJ when compared to other lysis techniques.
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Methods and Results: We retrospectively reviewed patients treated with thrombolysis over 5
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years. We identified those treated with Angiojet or catheter-directed thrombolysis (CDT).
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Demographics, indications, procedures and laboratory values within 3 days were recorded. AKI
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was defined as an increase >25% above the baseline creatinine within 72hrs of the procedure.
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102 patients (52 AJ, 50 CDT) had no statistical difference in mean age (50 and 51), indication
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(arterial thrombosis 65% and 88%), or baseline creatinine (0.9 mg/dL and 1.0 mg/dL),
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respectively. AKI occurred in 15(29%) treated with AJ, versus 4(8%) of CDT(P=0.007).
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Similar numbers of AJ and CDT patients underwent additional open surgical procedures
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(21% and 30%, respectively P=NS). Multivariable analysis demonstrated that the odds of AKI
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were only increased by AJ (OR 8.2 P=0.004, 95% CI 1.98-34.17), open surgery (OR 5.4
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P=0.013, 95% CI 1.43-20.17) or a >10% drop in hematocrit (OR 4.0 P=0.03, 95% CI 1.15-
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14.25).
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Conclusions: In our observational study, AJ is an independent risk factor for AKI. Concomitant
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open surgery and drop in hematocrit also raise the odds of AKI. Renal injury after AJ is under-
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reported in the literature, and may be related to hemolysis from the device.
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Introduction Percutaneous pharmacomechanical thrombectomy (PMT) is a popular and useful tool for
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rapid thrombus removal in acute thrombotic syndromes. It incorporates physical manipulation of
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the thrombus with intravascular delivery of thrombolytic solutions to increase the speed and
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efficiency of lysis. PMT using a variety of devices has been embraced for the treatment of both
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arterial 1, 2 and venous 3-5 acute thrombotic syndromes. The evidence-guided role for PTM over
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other techniques remains unclear, while it is recommended over simple, catheter-directed
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thrombolysis (CDT) in venous thrombolysis in the guidelines published by the American Venous
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Forum 6, while the American College of Chest physicians recommend using open surgical
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thrombectomy over any type of thrombolysis for arterial occlusions7.
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The AngioJet Rheolytic Thrombectomy System (Possis Medical, Minneapolis, MN) is a
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PMT device that uses a high-velocity spray designed to fragment clots, and is usually combined
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with solutions containing plasminogen activators (lytics) as the spray. In addition, retrograde-
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directed jets also create a negative pressure Bernoulli effect, which aspirates some of the
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fragmented blood and clot 8. When compared to standard catheter-directed thrombolysis or high-
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dose systemic infusions of fibrinolytics, Angiojet can potentially reduce the treatment time, total
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volume of fibrinolytic, ICU and hospital lengths of stay, hospital costs and even lower bleeding
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complications 9, 10. However, there has not been a randomized trial confirming these findings,
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and in some series there may be no difference in treatment times.
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However, a consequence of intravascular high-pressure jet spray is not only clot
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dissipation, but also significant destruction of red blood cells leading to hemolysis. All patients
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treated by Angiojet manifest some degree of hematuria11, and gross hematuria is typically seen
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(Figure 1). Practitioners generally manage this as a benign side-effect, and “hematuria” is not
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mentioned (or considered a complication) in clinical manuscripts using Angiojet. Despite this,
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acute hemolysis is a well-established cause of renal failure in other scenarios, such as
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paroxysmal nocturnal hemoglobinuria and failing mechanical heart valves 12, 13. Dukkipati et al. reported a case of acute kidney injury (AKI) after the use of Angiojet in a
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young patient with pulmonary embolism 13. Despite this report, we are not aware of any
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subsequent publication reporting, or evaluating adverse effects after using this device on renal
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function. Recently, the PEARL Angiojet registry mentioned the need for dialysis attributable to
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Angiojet in 5% of the patients enrolled, but did not report the incidence of acute renal injury,
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worsening renal function 14, nor offer a proposed cause for needing dialysis in these patients. We
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sought to determine if patients undergoing Angiojet thrombolysis were at increased risk of acute
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renal injury, when compared to non-Angiojet catheter-directed thrombolysis and identify other
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contributory variables.
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Methods:
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With institutional review board approval, we retrospectively reviewed a prospectivelymaintained database of patients at our institution from 2007-2013 with procedural codes related
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to thrombolysis (CPT 37201, 37187, 37209 and 75898), and/or Percutaneous Mechanical
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Thrombectomy (CPT 37187). Consent was not obtained as there was less than minimal risk to
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the patient, and no direct benefit to those enrolled was anticipated based on our findings. The
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approach of treatment was up to the practitioner at the time of the intervention, and not
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protocoled. We identified which patients were treated with Angiojet and collected demographics,
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indications, laboratory values before and after the procedure (up to 3 days) and determined the
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incidence of acute kidney injury (AKI). Chronic kidney disease was diagnosed as any patient
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with that diagnosis documented by a nephrologist prior to our procedure, or anyone with a
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baseline creatinine of 1.5mg/dL or greater. There are no published criteria for detecting acute kidney injury from hemolysis, therefore we used a clinical definition commonly attributed for contrast-induced nephropathy.
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AKI was defined as an increase in creatinine (Cr) >25% of baseline within 72hrs15, 16 or an
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absolute increase >0.5mg/dL. Patients on dialysis before Angiojet, duplicated codes, or those
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without lab values obtained before and 24-72hrs after treatment were excluded for analysis. We
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used the “worst” laboratory results within this time frame for our analysis (eg. the lowest
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hematocrit and highest creatinine) We chose to report creatinine rise as the measure for acute
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kidney injury, rather than a decrease in GFR because the only variable in the GFR calculation
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that would change in 72hrs would be the creatinine (age and weight would be unchanged). Thus,
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with a rise in creatinine, there would be a proportionate drop in GFR regardless of which is
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analyzed. All patients were exposed to 270mgI/mL Iodixanol (Visipaque, GE Healthcare,
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Princeton NJ, USA) which is a hyposmolar, non-ionic iodinated contrast agent.
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We also collected the same data in patients treated with catheter-directed thrombolysis (CDT) alone, and compared these outcomes to the Angiojet (AJ) group. Statistical analysis was performed using GraphPad Prism 6 software (GraphPad, La Jolla,
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CA) and Stata 12.1 (StataCorp LP, College Station, Texas). Pearson’s exact test was used for
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univariate analysis, two-tailed T-test analysis was used to compare two groups as paired or
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unpaired variables. Logistic regression was used to assess the relationship between AJ use and
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AKI. Confidence intervals were considered at 95% and statistical significance was accepted with
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a P<0.05. A Bonferroni correction was calculated for each variable that was assessed.
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Biological systems have multiple risk factors that may act in combination to increase the odds of acute renal injury, and not just the one we are studying (Angiojet). In order to better
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evaluate the “direct” and “indirect” effects of our variables on developing acute kidney injury,
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we wanted to evaluate them using another statistical approach to help “confirm” our findings. To
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do this, we created a “causal model” using our variables (like a flow diagram) leading to acute
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kidney injury using DAGitty software. This may help us re-evaluate if interactions appear among
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variables that may not be identified with standard univariable and logistic regression analysis, or
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correct our results if their significance was overestimated by not considering that one variable
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was unduly influenced by the presence of another. Causal model analysis offers a visual and
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statistical way to determine the minimal “adjustment sets” (statistical models) needed to estimate
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the “total effect” of Angiojet on causing AKI and estimate the “direct effect” of any one variable
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on developing AKI 17, 18.
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Results:
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102 patients who were treated with endovascular techniques for thrombotic syndromes,
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and had complete data were included for analysis. Of these, 52 were treated with Angiojet and 50
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with traditional CDT. Table 1 describes the pre-procedure (baseline) characteristics in each
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group, none of which were significantly different. Creatinine kinase and myoglobin levels were
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not collected before and after treatment in most of the patients studied and could not be included
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for analysis. The average age was 50 (range 20-87, median 49), and the average baseline
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creatinine was similar. The average hematocrit (HCT) before treatment was similar between both
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groups. Arterial thrombolysis was the indication in 34 (65%) of the AJ group, and 44 (88%) in
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the CDT group, and the rest were venous. Only 4 AJ patients (8%) and 8 CDT (16%) had a
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baseline Cr >1.4mg/dL before the procedures.
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Higher incidence of AKI after AJ versus CDI
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Acute kidney injury occurred in 15/52 (29%) patients treated with Angiojet (AKI group) which accounted for 79% of all cases of AKI, while only 4/50 (8%) of the CDT had AKI
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(P=0.007) (Figure 2). The mean absolute rise in creatinine in the AKI group was 0.5mg/dL,
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which was on average 61% higher than their baseline, p=0.003. This was not explained by pre-
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operative chronic renal failure as the baseline Cr before AJ in the patients who developed AKI
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was similar to that in the AJ patients who did not get AKI (P=0.1). Treatment of arterial
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thrombosis was the indication in 16 (84%) of all AKI cases. Two patients (both in AJ group)
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required dialysis within 2 days of their procedure, and died during their hospitalization (the
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causes of death were mesenteric ischemia and pulmonary embolus).
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Open surgery increases odds of AKI, especially in AJ
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Of 26 patients that had open surgery during the study period, a similar number of patients
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were from the Angiojet and CDT groups, 11(42%) and 15(58%), respectively. The AJ group had
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14 procedures, while 20 procedures were done in the CDT group (Table 2). Most of the
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procedures in the CDT group were open thromboembolectomy (9), and five had fasciotomies,
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four had a bypass or endarterectomy and only two had a major amputation. In the AJ group, five
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patients each had fasciotomies and/or thromboembolectomy, while three had a bypass or
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endarterectomy and there was only one major amputation. There was no statistically significant
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difference in the incidence of these surgeries in each lysis group.
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Nine (35%) of the surgery patients developed AKI, 8 of these were treated with Angiojet
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and 1 from the CDT group. Of the AJ patients who developed AKI, their average age was 54
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(range 36-74, median 46), 56% were male, 2 had diabetes, and three had a baseline Cr higher
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than 1.4mg/dL. Of Angiojet patients that underwent surgery, 53% (8/15) had AKI, while only
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9% (1/11) of CDT (non-AJ) that had surgery suffered AKI. This interaction was best
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demonstrated in figure 3 where those that underwent surgery and AJ had the largest rise in Cr
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(P=0.001) compared to any other group. Drop in Hematocrit (HCT) >10% independently increases odds of AKI
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Comparing the absolute post procedure hematocrit between the AJ and CDT groups
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demonstrated significantly lower levels in the AJ group (p=0.004), although the absolute
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difference between both groups (4%) is small (mean HCT 32% vs 36%, Median 32% vs 32%,
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respectively). However, when we evaluated blood loss as a function of the percent change from
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baseline in the Angiojet vs. non-Angiojet controls, there was not only a statistically significant
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difference, but also a more clinically relevant change. The CDT group decreased by only 5% of
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their baseline as opposed to the Angiojet group, which decreased by 12% (P=0.009, 95% CI of
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1.8 to 11.9), and the increase in odds was even more apparent when we looked at the change in
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hematocrit in patients that did or did not have AKI (Figure 4). Based on this finding, we
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analyzed the odds ratio of AKI after a drop in hematocrit of at least 10% in our univariable and
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multivariable modeling.
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Univariate analysis is presented in figure 5 and revealed that treatment with AJ, open
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surgery or a drop in hematocrit of at least 10% significantly increased the odds ratio of AKI.
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Multivariable logistic regression analysis shown in figure 6 confirmed these three variables as
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significant risk factors that raise the odds of AKI (OR 8.22, P=0.004, 95% CI 1.98-34.17 for
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Angiojet, OR 5.38 P=0.013 CI 1.43-20.17 for surgery and OR 4.04 P=0.03, 95% CI 1.17-14.25
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for hematocrit drop of 10% or more). We additionally evaluated if the indication for the
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procedure (arterial or venous thrombosis) influenced the odds of developing AKI, we did not
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find any statistically significant risk (OR 0.4446706, P=0.303, 95% CI 0.095-2.08).
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In order to strengthen our findings above of Angiojet on the development of AKI, we analyzed the odds ratio of Angiojet leading to AKI using a directed acyclic graph which
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identified their potential interactions (Figure 7). DAGitty analysis of the diagram determined that
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to estimate the total effect of AJ on AKI required statistical analysis of the following groups of
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variables: age and arterial indication, age and chronic renal failure (CRF) and diabetes (DM),
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arterial indication versus venous indication, CRF and DM and venous indication. To determine
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the direct effect of AJ and the risk of developing AKI, statistical models should also include age,
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indication for procedure, hematocrit drop and surgery; as each of these could independently
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cause AKI. Individual statistical modeling for each of these groups of variables was not
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statistically significant (data available upon request) and our findings were unchanged after DAG
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analysis.
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Thus, AJ remained as a statistically significant risk factor for developing AKI, with an odds ratio which was greater than 8; and both surgery and a drop in hematrocrit >10% from
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baseline increase the odds ratio for AKI in a statistically significant manner.
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In our institution, we found that the use of Angiojet for thrombolysis significantly
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increased the odds of developing AKI by a factor of eight. This large difference was independent
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of other comorbidities that are traditionally associated with AKI. AKI occurred in AJ patients as
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young as 36 years old, and only two of the AJ patients in the AKI group had diabetes.
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While the final hematocrit was similar in both groups, we were surprised to find that the
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change in hematocrit after the procedure independently increased the risk of AKI. It was also
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remarkable that patients treated with Angiojet who developed AKI had the largest drop in
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hematocrit compared to all other groups of patients, even when accounting for surgical
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procedures (figure 4). Of note, the hematocrit in this group averaged 29% (hemoglobin of
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~9g/dL) so these patients were certainly not profoundly anemic during their treatment period,
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and this anemia would not pass the typical threshold for transfusion (and was similar in both
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groups). This implies that anemia alone is unlikely the cause for renal injury. If the drop in
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hemoglobin was only from iatrogenic dilution, then the creatinine would have also fallen in
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tandem and thus lowered the likelihood of diagnosing AKI (in which case we would be
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underestimating the incidence of AKI by having lower creatinine values). Thus, we speculate
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that the larger hematocrit drop in the AJ patients may be a marker of hemolysis from the device,
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which in turn may be contributing to the higher incidence of renal injury in those treated with AJ.
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Renal failure from acute hemolysis seems to occur after one of two different scenarios. Free serum hemoglobin normally binds to plasma haptoglobin, but when this becomes saturated,
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the remaining free hemoglobin forms a dimer which is filtered into the renal tubules.
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Hemoglobin is reabsorbed and dissociates intracellularly to heme and globin, which is cytotoxic.
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The other renally-caustic mechanism is that heme can bind to Tamm-Horsefall proteins in the
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renal tubules which forms intratubular casts that physically occlude tubular flow, leading to
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oliguria and azotemia 19, 20.
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function. Lin et al. evaluated vessel injury in porcine models with Angiojet with or without
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thrombolysis solutions, but they did not study the effects on renal function or effects of
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hemolysis 21. The CaVenT registry reported the outcomes of the use of thrombolysis (including
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Angiojet) for venous occlusions, but did not include the results of renal function, even in its
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long-term outcomes publication 5, 22. The large, multicenter, randomized ATTRACT trial also
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does not seem to be including renal function in its data collection 23. A report evaluating the
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management of thromboembolic complications after angioplasty used Angiojet in 14/18 cases.
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They stated that “No hemoglobinuria or renal dysfunction or failure was noted” 24, but it is not
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clear in the manuscript if this was referring only in the three patients in the series that died, or
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their study population in toto; especially given that most patients treated with Angiojet have
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some degree of hemoglobinuria. The recently published PEARL registry assessing 283 patients
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with acute limb ischemia treated with AJ found 5% developed renal failure requiring dialysis
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directly attributable to AJ. Dialysis dependence was permanent in ¾ of these patients. We had 2
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patients require dialysis after AJ (4%) which although was a similar incidence, a direct
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correlation of AJ in our cases was not possible.
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Acute renal injury is important to measure and detect, even if no dialysis is needed acutely. Overwhelming intravascular hemolysis from various causes can result in acute tubular
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necrosis and fulminant renal failure, but it has also been found that long-standing exposures to
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lower degrees of hemolysis can lead to hemosiderin depositing in the kidneys, ultimately leading
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to renal failure 25. The odds ratio of death or intracranial hemorrhage after thrombolysis is almost
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2.5 if the patient develops renal failure 26. This implies that every renal injury counts, and even
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when the patient’s creatinine does not seem to change initially, the damage to the kidney may be
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cumulative 27. Thus, patients who require thrombolysis for restoration of arterial blood flow may
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be at increased risk, because re-occlusion is common 2 leading to repeated therapy with Angiojet.
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We acknowledge several limitations to our study. We had limited numbers of patients
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treated with Angiojet, although our series is comparable or larger than most published datasets
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that evaluated the device’s efficacy for clot resolution in comparison to CDT. We could not
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control for contrast-induced nephropathy (CIN) as a potential cause for AKI because the volume
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was not always included in the operative reports, and was not available to us in the data
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extraction model we had access to. On the other hand, at our institution we only use 270mgI/mL
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Iodixanol for intravascular procedures; and this iodinated contrast agent has the lowest reported
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incidence of CIN given its hypo-osmolar, non-ionic properties. We are also encouraged that this
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alone is unlikely to account for the large difference, as we studied the outcomes in two groups of
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patients who were both treated with endovascular techniques that required exposure to iodinated
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contrast agent. In addition, Angiojet should theoretically reduce contrast exposure by reducing
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the treatment times and the number of contrast boluses needed for the repeated “lysis checks”
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needed in traditional catheter-directed thrombolysis; thus we do not think that contrast exposure
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alone could account for our large difference in odds ratio by multivariable and DAG statistical
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analysis. Finally, rhabdomyolysis from ischemia/reperfusion in some of these cases could
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certainly contribute to a risk of AKI, especially as nearly all of the patients with creatinine
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elevation were treated for arterial thrombus. Unfortunately, only a few patients had myoglobin or
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creatinine kinase levels drawn before and after the lysis procedure. However, rhabdomyolysis
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alone is also unlikely to explain the odds ratio greater than 8 in the AJ group, given that almost
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90% of the control (CDT group) was treated for arterial thrombosis (compared to only 65% of
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AJ), and few patients required amputations or fasciotomies in either group. When we analyzed
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the indication of the procedure (venous thrombolysis or arterial) as a risk factor, we did not find
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any statistically significant difference in the odds of developing AKI, although this is not
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definitive given the smaller numbers involved. If significant rhabdomyolysis alone were the
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predominate cause of this difference, then we would have expected more patients would have
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either had fasciotomies, or subsequent amputations in the AKI group, which was not found.
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Nevertheless, we certainly acknowledge that we cannot exclude this as a contributing factor in
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this retrospective review.
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In summary, AJ significantly increases the odds of renal injury when compared to CDT and is known to cause hemolysis. AJ has been directly linked to dialysis-dependent renal failure
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in at least one large registry and in one published case report. We believe that hemolysis is not
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benign to the kidney either acutely or chronically, and patients treated for recurrent thrombotic
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syndromes may be at higher risk to both. Further study being done at our institution to better
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identify other causal risk factors (Angiojet treatment times, time intervals between treatments,
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duration of hematuria post-procedure, improved quantification of blood loss etc.) so as to better
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define the ideal patients and techniques to optimally use AJ for acute intravascular thrombosis.
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1. Valji K, Roberts AC, Davis GB, Bookstein JJ. Pulsed-spray thrombolysis of arterial and bypass graft occlusions. AJR Am J Roentgenol. 1991;156(3):617-21. 2. Comerota AJ, Weaver FA, Hosking JD, Froehlich J, Folander H, Sussman B, et al. Results of a prospective, randomized trial of surgery versus thrombolysis for occluded lower extremity bypass grafts. Am J Surg. 1996;172(2):105-12. 3. Lin PH, Zhou W, Dardik A, Mussa F, Kougias P, Hedayati N, et al. Catheter-direct thrombolysis versus pharmacomechanical thrombectomy for treatment of symptomatic lower extremity deep venous thrombosis. Am J Surg. 2006;192(6):782-8. 4. Comerota AJ, Throm RC, Mathias SD, Haughton S, Mewissen M. Catheter-directed thrombolysis for iliofemoral deep venous thrombosis improves health-related quality of life. J Vasc Surg. 2000;32(1):130-7. 5. Enden T, Haig Y, Klow NE, Slagsvold CE, Sandvik L, Ghanima W, et al. Long-term outcome after additional catheter-directed thrombolysis versus standard treatment for acute iliofemoral deep vein thrombosis (the CaVenT study): a randomised controlled trial. Lancet. 2012;379(9810):31-8. 6. Meissner MH, Gloviczki P, Comerota AJ, Dalsing MC, Eklof BG, Gillespie DL, et al. Early thrombus removal strategies for acute deep venous thrombosis: clinical practice guidelines of the Society for Vascular Surgery and the American Venous Forum. J Vasc Surg. 2012;55(5):1449-62. 7. Alonso-Coello P, Bellmunt S, McGorrian C, Anand SS, Guzman R, Criqui MH, et al. Antithrombotic therapy in peripheral artery disease: Antithrombotic Therapy and Prevention of Thrombosis, 9th ed: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines. Chest. 2012;141(2 Suppl):e669S-90S. 8. Sharafuddin MJ, Hicks ME. Current status of percutaneous mechanical thrombectomy. Part I. General principles. J Vasc Interv Radiol. 1997;8(6):911-21. 9. Allie DE, Hebert CJ, Lirtzman MD, Wyatt CH, Keller VA, Khan MH, et al. Novel simultaneous combination chemical thrombolysis/rheolytic thrombectomy therapy for acute critical limb ischemia: the power-pulse spray technique. Catheter Cardiovasc Interv. 2004;63(4):512-22. 10. Bush RL, Lin PH, Bates JT, Mureebe L, Zhou W, Lumsden AB. Pharmacomechanical thrombectomy for treatment of symptomatic lower extremity deep venous thrombosis: safety and feasibility study. J Vasc Surg. 2004;40(5):965-70. 11. Ouriel K. Endovascular techniques in the treatment of acute limb ischemia: thrombolytic agents, trials, and percutaneous mechanical thrombectomy techniques. Semin Vasc Surg. 2003;16(4):270-9. 12. Concepcion B, Korbet SM, Schwartz MM. Intravascular hemolysis and acute renal failure after mitral and aortic valve repair. Am J Kidney Dis. 2008;52(5):1010-5. 13. Dukkipati R, Yang EH, Adler S, Vintch J. Acute kidney injury caused by intravascular hemolysis after mechanical thrombectomy. Nat Clin Pract Nephrol. 2009;5(2):112-6. 14. Leung DA, Blitz LR, Nelson T, Amin A, Soukas PA, Nanjundappa A, et al. Rheolytic Pharmacomechanical Thrombectomy for the Management of Acute Limb Ischemia: Results From the PEARL Registry. J Endovasc Ther. 2015;22(4):546-57. 15. Rezaei Y, Khademvatani K, Rahimi B, Khoshfetrat M, Arjmand N, SeyyedMohammadzad MH. Short-Term High-Dose Vitamin E to Prevent Contrast Medium-Induced
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Acute Kidney Injury in Patients With Chronic Kidney Disease Undergoing Elective Coronary Angiography: A Randomized Placebo-Controlled Trial. J Am Heart Assoc. 2016;5(3). 16. Centola M, Lucreziotti S, Salerno-Uriarte D, Sponzilli C, Ferrante G, Acquaviva R, et al. A comparison between two different definitions of contrast-induced acute kidney injury in patients with ST-segment elevation myocardial infarction undergoing primary percutaneous coronary intervention. Int J Cardiol. 2016;210:4-9. 17. Textor J, Hardt J, Knuppel S. DAGitty: a graphical tool for analyzing causal diagrams. Epidemiology. 2011;22(5):745. 18. Textor J. Daggity Software. 2013 [cited 2015]; 2.1:[Available from: http://www.dagitty.net. 19. Qian Q, Nath KA, Wu Y, Daoud TM, Sethi S. Hemolysis and acute kidney failure. Am J Kidney Dis. 2010;56(4):780-4. 20. Nath KA, Grande JP, Croatt AJ, Likely S, Hebbel RP, Enright H. Intracellular targets in heme protein-induced renal injury. Kidney Int. 1998;53(1):100-11. 21. Lin PH, Mussa FF, Hedayati N, Naoum JJ, Zhou W, Yao Q, et al. Comparison of AngioJet rheolytic pharmacomechanical thrombectomy versus AngioJet rheolytic thrombectomy in a porcine peripheral arterial model. World J Surg. 2007;31(4):715-22. 22. Enden T, Sandvik L, Klow NE, Hafsahl G, Holme PA, Holmen LO, et al. Catheterdirected Venous Thrombolysis in acute iliofemoral vein thrombosis--the CaVenT study: rationale and design of a multicenter, randomized, controlled, clinical trial (NCT00251771). Am Heart J. 2007;154(5):808-14. 23. Comerota AJ. The ATTRACT trial: rationale for early intervention for iliofemoral DVT. Perspect Vasc Surg Endovasc Ther. 2009;21(4):221-4; quiz 4-5. 24. Spiliopoulos S, Katsanos K, Fragkos G, Karnabatidis D, Siablis D. Treatment of infrainguinal thromboembolic complications during peripheral endovascular procedures with AngioJet rheolytic thrombectomy, intraoperative thrombolysis, and selective stenting. J Vasc Surg. 2012;56(5):1308-16. 25. Ackermann D, Vogt B, Gugger M, Marti HP. Renal haemosiderosis: an unusual presentation of acute renal failure in a patient following heart valve prosthesis. Nephrol Dial Transplant. 2004;19(10):2682-3. 26. Bashir R, Zack CJ, Zhao H, Comerota AJ, Bove AA. Comparative outcomes of catheterdirected thrombolysis plus anticoagulation vs anticoagulation alone to treat lower-extremity proximal deep vein thrombosis. JAMA Intern Med. 2014;174(9):1494-501. 27. Nath KA, Croatt AJ, Haggard JJ, Grande JP. Renal response to repetitive exposure to heme proteins: chronic injury induced by an acute insult. Kidney Int. 2000;57(6):2423-33.
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Figure 1
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A) Panel A (left) shows gross hematuria being collected in a urine collection tubing
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B) Demonstrates the progression of hematuria from normal, clear urine prior to Angiojet (black arrow), followed by the progressively denser hematuria (white arrow).
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Figure 2
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Raw incidence of acute kidney injury (AKI) defined as an increase greater than 25% of baseline.
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(Angiojet = AJ, Catheter directed thrombolysis = CDT, Creatinine= Cr)
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Percent change in the creatinine in treated patients when exposed to additional open surgery.
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Dotted horizontal line indicates the threshold for definition of acute kidney injury (25% rise after
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the procedure). (Angiojet = AJ, Catheter directed thrombolysis =CDT)
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Figure 4
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Graph showing the effect of a drop in the hematocrit (as a percentage of baseline) after being
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treated with Angiojet (AJ) or catheter directed thrombolysis (CDT), in those that did, or did not
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have acute kidney injury (AKI).
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Figure 5
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Univariable analysis and forest plot to demonstrate Odds Ratios (OR) and 95% confidence
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intervals (CI) of variables expected to be related to development of AKI. Odds ratio axis is at a
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Log 5 scale. (Angiojet = AJ, Major open surgical procedures = Maj Surg, Chronic renal failure =
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CRF, patients with at least a 10% drop in their hematocrit = 10% Drop HCT)
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Multivariable logistic regression analysis and forest plot to demonstrate Odds Ratios (OR) and
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95% confidence intervals (CI) of variables expected to be related to development of AKI. Odds
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ratio axis is at a Log 5 scale. (Angiojet = AJ, Major open surgical procedures = Maj Surg,
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Chronic renal failure = CRF, patients with at least a 10% drop in their hematocrit = 10% Drop
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HCT)
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405 Figure 7
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Directed acyclic graphs (DAGs) using DAGitty software to determine the potential effects of
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each variable. The graph was created by the authors using background knowledge of potential
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interactions between the variables involved with lysis and developing AKI.
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Lysis procedure is the primary exposure and acute kidney injury (AKI) is the outcome. Red
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variables are potential confounders to the “total effect” of the lysis procedure on AKI, as they
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potentially influence both the primary exposure and AKI. Blue variables are those that may bias
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the “direct effect” of lysis procedure as they alone can cause AKI independently of the lysis
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procedure. Green variables are determinants to the Lysis and do not directly affect AKI. (Arterial
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thrombosis = Arterial_clot, Venous thrombosis = venous clot, Chronic renal failure = CRF,
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Diabetes mellitus = DM, Drop in hematocrit = Drop_Hematocrit)
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Table 1
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Patient baseline demographics comorbidities and lab values for angiojet patients and catheter-
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directed thrombolysis (CDT) patients. (Cr=Creatinine mg/dL, HCT= hematocrit, not significant
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= NS).
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Table 2
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Adjunct endovascular and surgical procedures done to each group
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S0890-5096(17)30646-5
DOI:
10.1016/j.avsg.2016.12.018
Reference:
AVSG 3263
To appear in:
Annals of Vascular Surgery
Received Date: 15 April 2016 Revised Date:
8 July 2016
Accepted Date: 5 December 2016
Please cite this article as: Escobar GA, Burks D, Abate MR, Faramawi MF, Ali AT, Lyons LC, Moursi MM, Smeds MR, Risk of acute kidney injury after percutaneous pharmacomechanical thrombectomy using Angiojet in venous and arterial thrombosis, Annals of Vascular Surgery (2017), doi: 10.1016/ j.avsg.2016.12.018. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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1 2 3 Risk of acute kidney injury after percutaneous pharmacomechanical thrombectomy using
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Angiojet in venous and arterial thrombosis
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Guillermo A. Escobar, MD, Dillon Burks, BS, Matthew R. Abate, MD, Mohammed F.
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Faramawi, MD, Ahsan T. Ali, MD, Lewis C. Lyons MD, Mohammed M. Moursi MD, and
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Matthew R. Smeds, MD
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Corresponding Author:
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Assistant Professor of Surgery, Vascular Surgery Division
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Guillermo A Escobar, MD
University of Arkansas for Medical Sciences
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4301 W Markham St. #520-2 Little Rock, AR 72205-7199
Phone (501) 686-6176, Fax (501) 686-5328 [email protected]
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24 Disclosures
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No author has a conflict of interest related to this research, and no external funding was obtained
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to obtain or analyze this data.
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Abstract
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Background: Percutaneous mechanical thrombectomy (PMT) is commonly used to treat acute
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thrombotic syndromes. Angiojet (AJ) forcibly sprays fibrinolytics to fragment and aspirate
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thrombus. It’s known to cause hemolysis and gross hematuria, yet potential consequences to
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renal function after AJ remain unstudied. We sought to determine the risk of acute kidney injury
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(AKI) after AJ when compared to other lysis techniques.
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Methods and Results: We retrospectively reviewed patients treated with thrombolysis over 5
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years. We identified those treated with Angiojet or catheter-directed thrombolysis (CDT).
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Demographics, indications, procedures and laboratory values within 3 days were recorded. AKI
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was defined as an increase >25% above the baseline creatinine within 72hrs of the procedure.
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102 patients (52 AJ, 50 CDT) had no statistical difference in mean age (50 and 51), indication
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(arterial thrombosis 65% and 88%), or baseline creatinine (0.9 mg/dL and 1.0 mg/dL),
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respectively. AKI occurred in 15(29%) treated with AJ, versus 4(8%) of CDT(P=0.007).
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Similar numbers of AJ and CDT patients underwent additional open surgical procedures
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(21% and 30%, respectively P=NS). Multivariable analysis demonstrated that the odds of AKI
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were only increased by AJ (OR 8.2 P=0.004, 95% CI 1.98-34.17), open surgery (OR 5.4
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P=0.013, 95% CI 1.43-20.17) or a >10% drop in hematocrit (OR 4.0 P=0.03, 95% CI 1.15-
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14.25).
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Conclusions: In our observational study, AJ is an independent risk factor for AKI. Concomitant
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open surgery and drop in hematocrit also raise the odds of AKI. Renal injury after AJ is under-
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reported in the literature, and may be related to hemolysis from the device.
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Introduction Percutaneous pharmacomechanical thrombectomy (PMT) is a popular and useful tool for
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rapid thrombus removal in acute thrombotic syndromes. It incorporates physical manipulation of
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the thrombus with intravascular delivery of thrombolytic solutions to increase the speed and
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efficiency of lysis. PMT using a variety of devices has been embraced for the treatment of both
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arterial 1, 2 and venous 3-5 acute thrombotic syndromes. The evidence-guided role for PTM over
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other techniques remains unclear, while it is recommended over simple, catheter-directed
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thrombolysis (CDT) in venous thrombolysis in the guidelines published by the American Venous
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Forum 6, while the American College of Chest physicians recommend using open surgical
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thrombectomy over any type of thrombolysis for arterial occlusions7.
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The AngioJet Rheolytic Thrombectomy System (Possis Medical, Minneapolis, MN) is a
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PMT device that uses a high-velocity spray designed to fragment clots, and is usually combined
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with solutions containing plasminogen activators (lytics) as the spray. In addition, retrograde-
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directed jets also create a negative pressure Bernoulli effect, which aspirates some of the
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fragmented blood and clot 8. When compared to standard catheter-directed thrombolysis or high-
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dose systemic infusions of fibrinolytics, Angiojet can potentially reduce the treatment time, total
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volume of fibrinolytic, ICU and hospital lengths of stay, hospital costs and even lower bleeding
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complications 9, 10. However, there has not been a randomized trial confirming these findings,
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and in some series there may be no difference in treatment times.
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However, a consequence of intravascular high-pressure jet spray is not only clot
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dissipation, but also significant destruction of red blood cells leading to hemolysis. All patients
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treated by Angiojet manifest some degree of hematuria11, and gross hematuria is typically seen
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(Figure 1). Practitioners generally manage this as a benign side-effect, and “hematuria” is not
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mentioned (or considered a complication) in clinical manuscripts using Angiojet. Despite this,
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acute hemolysis is a well-established cause of renal failure in other scenarios, such as
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paroxysmal nocturnal hemoglobinuria and failing mechanical heart valves 12, 13. Dukkipati et al. reported a case of acute kidney injury (AKI) after the use of Angiojet in a
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young patient with pulmonary embolism 13. Despite this report, we are not aware of any
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subsequent publication reporting, or evaluating adverse effects after using this device on renal
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function. Recently, the PEARL Angiojet registry mentioned the need for dialysis attributable to
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Angiojet in 5% of the patients enrolled, but did not report the incidence of acute renal injury,
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worsening renal function 14, nor offer a proposed cause for needing dialysis in these patients. We
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sought to determine if patients undergoing Angiojet thrombolysis were at increased risk of acute
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renal injury, when compared to non-Angiojet catheter-directed thrombolysis and identify other
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contributory variables.
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Methods:
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With institutional review board approval, we retrospectively reviewed a prospectivelymaintained database of patients at our institution from 2007-2013 with procedural codes related
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to thrombolysis (CPT 37201, 37187, 37209 and 75898), and/or Percutaneous Mechanical
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Thrombectomy (CPT 37187). Consent was not obtained as there was less than minimal risk to
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the patient, and no direct benefit to those enrolled was anticipated based on our findings. The
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approach of treatment was up to the practitioner at the time of the intervention, and not
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protocoled. We identified which patients were treated with Angiojet and collected demographics,
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indications, laboratory values before and after the procedure (up to 3 days) and determined the
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incidence of acute kidney injury (AKI). Chronic kidney disease was diagnosed as any patient
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with that diagnosis documented by a nephrologist prior to our procedure, or anyone with a
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baseline creatinine of 1.5mg/dL or greater. There are no published criteria for detecting acute kidney injury from hemolysis, therefore we used a clinical definition commonly attributed for contrast-induced nephropathy.
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AKI was defined as an increase in creatinine (Cr) >25% of baseline within 72hrs15, 16 or an
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absolute increase >0.5mg/dL. Patients on dialysis before Angiojet, duplicated codes, or those
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without lab values obtained before and 24-72hrs after treatment were excluded for analysis. We
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used the “worst” laboratory results within this time frame for our analysis (eg. the lowest
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hematocrit and highest creatinine) We chose to report creatinine rise as the measure for acute
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kidney injury, rather than a decrease in GFR because the only variable in the GFR calculation
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that would change in 72hrs would be the creatinine (age and weight would be unchanged). Thus,
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with a rise in creatinine, there would be a proportionate drop in GFR regardless of which is
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analyzed. All patients were exposed to 270mgI/mL Iodixanol (Visipaque, GE Healthcare,
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Princeton NJ, USA) which is a hyposmolar, non-ionic iodinated contrast agent.
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We also collected the same data in patients treated with catheter-directed thrombolysis (CDT) alone, and compared these outcomes to the Angiojet (AJ) group. Statistical analysis was performed using GraphPad Prism 6 software (GraphPad, La Jolla,
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CA) and Stata 12.1 (StataCorp LP, College Station, Texas). Pearson’s exact test was used for
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univariate analysis, two-tailed T-test analysis was used to compare two groups as paired or
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unpaired variables. Logistic regression was used to assess the relationship between AJ use and
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AKI. Confidence intervals were considered at 95% and statistical significance was accepted with
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a P<0.05. A Bonferroni correction was calculated for each variable that was assessed.
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Biological systems have multiple risk factors that may act in combination to increase the odds of acute renal injury, and not just the one we are studying (Angiojet). In order to better
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evaluate the “direct” and “indirect” effects of our variables on developing acute kidney injury,
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we wanted to evaluate them using another statistical approach to help “confirm” our findings. To
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do this, we created a “causal model” using our variables (like a flow diagram) leading to acute
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kidney injury using DAGitty software. This may help us re-evaluate if interactions appear among
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variables that may not be identified with standard univariable and logistic regression analysis, or
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correct our results if their significance was overestimated by not considering that one variable
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was unduly influenced by the presence of another. Causal model analysis offers a visual and
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statistical way to determine the minimal “adjustment sets” (statistical models) needed to estimate
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the “total effect” of Angiojet on causing AKI and estimate the “direct effect” of any one variable
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on developing AKI 17, 18.
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Results:
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102 patients who were treated with endovascular techniques for thrombotic syndromes,
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and had complete data were included for analysis. Of these, 52 were treated with Angiojet and 50
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with traditional CDT. Table 1 describes the pre-procedure (baseline) characteristics in each
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group, none of which were significantly different. Creatinine kinase and myoglobin levels were
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not collected before and after treatment in most of the patients studied and could not be included
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for analysis. The average age was 50 (range 20-87, median 49), and the average baseline
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creatinine was similar. The average hematocrit (HCT) before treatment was similar between both
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groups. Arterial thrombolysis was the indication in 34 (65%) of the AJ group, and 44 (88%) in
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the CDT group, and the rest were venous. Only 4 AJ patients (8%) and 8 CDT (16%) had a
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baseline Cr >1.4mg/dL before the procedures.
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Higher incidence of AKI after AJ versus CDI
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Acute kidney injury occurred in 15/52 (29%) patients treated with Angiojet (AKI group) which accounted for 79% of all cases of AKI, while only 4/50 (8%) of the CDT had AKI
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(P=0.007) (Figure 2). The mean absolute rise in creatinine in the AKI group was 0.5mg/dL,
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which was on average 61% higher than their baseline, p=0.003. This was not explained by pre-
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operative chronic renal failure as the baseline Cr before AJ in the patients who developed AKI
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was similar to that in the AJ patients who did not get AKI (P=0.1). Treatment of arterial
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thrombosis was the indication in 16 (84%) of all AKI cases. Two patients (both in AJ group)
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required dialysis within 2 days of their procedure, and died during their hospitalization (the
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causes of death were mesenteric ischemia and pulmonary embolus).
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Open surgery increases odds of AKI, especially in AJ
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Of 26 patients that had open surgery during the study period, a similar number of patients
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were from the Angiojet and CDT groups, 11(42%) and 15(58%), respectively. The AJ group had
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14 procedures, while 20 procedures were done in the CDT group (Table 2). Most of the
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procedures in the CDT group were open thromboembolectomy (9), and five had fasciotomies,
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four had a bypass or endarterectomy and only two had a major amputation. In the AJ group, five
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patients each had fasciotomies and/or thromboembolectomy, while three had a bypass or
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endarterectomy and there was only one major amputation. There was no statistically significant
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difference in the incidence of these surgeries in each lysis group.
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Nine (35%) of the surgery patients developed AKI, 8 of these were treated with Angiojet
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and 1 from the CDT group. Of the AJ patients who developed AKI, their average age was 54
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(range 36-74, median 46), 56% were male, 2 had diabetes, and three had a baseline Cr higher
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than 1.4mg/dL. Of Angiojet patients that underwent surgery, 53% (8/15) had AKI, while only
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9% (1/11) of CDT (non-AJ) that had surgery suffered AKI. This interaction was best
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demonstrated in figure 3 where those that underwent surgery and AJ had the largest rise in Cr
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(P=0.001) compared to any other group. Drop in Hematocrit (HCT) >10% independently increases odds of AKI
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Comparing the absolute post procedure hematocrit between the AJ and CDT groups
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demonstrated significantly lower levels in the AJ group (p=0.004), although the absolute
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difference between both groups (4%) is small (mean HCT 32% vs 36%, Median 32% vs 32%,
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respectively). However, when we evaluated blood loss as a function of the percent change from
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baseline in the Angiojet vs. non-Angiojet controls, there was not only a statistically significant
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difference, but also a more clinically relevant change. The CDT group decreased by only 5% of
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their baseline as opposed to the Angiojet group, which decreased by 12% (P=0.009, 95% CI of
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1.8 to 11.9), and the increase in odds was even more apparent when we looked at the change in
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hematocrit in patients that did or did not have AKI (Figure 4). Based on this finding, we
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analyzed the odds ratio of AKI after a drop in hematocrit of at least 10% in our univariable and
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multivariable modeling.
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Univariate analysis is presented in figure 5 and revealed that treatment with AJ, open
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surgery or a drop in hematocrit of at least 10% significantly increased the odds ratio of AKI.
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Multivariable logistic regression analysis shown in figure 6 confirmed these three variables as
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significant risk factors that raise the odds of AKI (OR 8.22, P=0.004, 95% CI 1.98-34.17 for
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Angiojet, OR 5.38 P=0.013 CI 1.43-20.17 for surgery and OR 4.04 P=0.03, 95% CI 1.17-14.25
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for hematocrit drop of 10% or more). We additionally evaluated if the indication for the
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procedure (arterial or venous thrombosis) influenced the odds of developing AKI, we did not
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find any statistically significant risk (OR 0.4446706, P=0.303, 95% CI 0.095-2.08).
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In order to strengthen our findings above of Angiojet on the development of AKI, we analyzed the odds ratio of Angiojet leading to AKI using a directed acyclic graph which
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identified their potential interactions (Figure 7). DAGitty analysis of the diagram determined that
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to estimate the total effect of AJ on AKI required statistical analysis of the following groups of
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variables: age and arterial indication, age and chronic renal failure (CRF) and diabetes (DM),
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arterial indication versus venous indication, CRF and DM and venous indication. To determine
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the direct effect of AJ and the risk of developing AKI, statistical models should also include age,
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indication for procedure, hematocrit drop and surgery; as each of these could independently
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cause AKI. Individual statistical modeling for each of these groups of variables was not
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statistically significant (data available upon request) and our findings were unchanged after DAG
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analysis.
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Thus, AJ remained as a statistically significant risk factor for developing AKI, with an odds ratio which was greater than 8; and both surgery and a drop in hematrocrit >10% from
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baseline increase the odds ratio for AKI in a statistically significant manner.
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In our institution, we found that the use of Angiojet for thrombolysis significantly
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increased the odds of developing AKI by a factor of eight. This large difference was independent
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of other comorbidities that are traditionally associated with AKI. AKI occurred in AJ patients as
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young as 36 years old, and only two of the AJ patients in the AKI group had diabetes.
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While the final hematocrit was similar in both groups, we were surprised to find that the
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change in hematocrit after the procedure independently increased the risk of AKI. It was also
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remarkable that patients treated with Angiojet who developed AKI had the largest drop in
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hematocrit compared to all other groups of patients, even when accounting for surgical
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procedures (figure 4). Of note, the hematocrit in this group averaged 29% (hemoglobin of
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~9g/dL) so these patients were certainly not profoundly anemic during their treatment period,
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and this anemia would not pass the typical threshold for transfusion (and was similar in both
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groups). This implies that anemia alone is unlikely the cause for renal injury. If the drop in
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hemoglobin was only from iatrogenic dilution, then the creatinine would have also fallen in
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tandem and thus lowered the likelihood of diagnosing AKI (in which case we would be
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underestimating the incidence of AKI by having lower creatinine values). Thus, we speculate
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that the larger hematocrit drop in the AJ patients may be a marker of hemolysis from the device,
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which in turn may be contributing to the higher incidence of renal injury in those treated with AJ.
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Renal failure from acute hemolysis seems to occur after one of two different scenarios. Free serum hemoglobin normally binds to plasma haptoglobin, but when this becomes saturated,
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the remaining free hemoglobin forms a dimer which is filtered into the renal tubules.
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Hemoglobin is reabsorbed and dissociates intracellularly to heme and globin, which is cytotoxic.
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The other renally-caustic mechanism is that heme can bind to Tamm-Horsefall proteins in the
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renal tubules which forms intratubular casts that physically occlude tubular flow, leading to
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oliguria and azotemia 19, 20.
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function. Lin et al. evaluated vessel injury in porcine models with Angiojet with or without
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thrombolysis solutions, but they did not study the effects on renal function or effects of
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hemolysis 21. The CaVenT registry reported the outcomes of the use of thrombolysis (including
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Angiojet) for venous occlusions, but did not include the results of renal function, even in its
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long-term outcomes publication 5, 22. The large, multicenter, randomized ATTRACT trial also
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does not seem to be including renal function in its data collection 23. A report evaluating the
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management of thromboembolic complications after angioplasty used Angiojet in 14/18 cases.
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They stated that “No hemoglobinuria or renal dysfunction or failure was noted” 24, but it is not
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clear in the manuscript if this was referring only in the three patients in the series that died, or
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their study population in toto; especially given that most patients treated with Angiojet have
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some degree of hemoglobinuria. The recently published PEARL registry assessing 283 patients
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with acute limb ischemia treated with AJ found 5% developed renal failure requiring dialysis
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directly attributable to AJ. Dialysis dependence was permanent in ¾ of these patients. We had 2
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patients require dialysis after AJ (4%) which although was a similar incidence, a direct
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correlation of AJ in our cases was not possible.
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Acute renal injury is important to measure and detect, even if no dialysis is needed acutely. Overwhelming intravascular hemolysis from various causes can result in acute tubular
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necrosis and fulminant renal failure, but it has also been found that long-standing exposures to
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lower degrees of hemolysis can lead to hemosiderin depositing in the kidneys, ultimately leading
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to renal failure 25. The odds ratio of death or intracranial hemorrhage after thrombolysis is almost
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2.5 if the patient develops renal failure 26. This implies that every renal injury counts, and even
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when the patient’s creatinine does not seem to change initially, the damage to the kidney may be
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cumulative 27. Thus, patients who require thrombolysis for restoration of arterial blood flow may
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be at increased risk, because re-occlusion is common 2 leading to repeated therapy with Angiojet.
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We acknowledge several limitations to our study. We had limited numbers of patients
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treated with Angiojet, although our series is comparable or larger than most published datasets
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that evaluated the device’s efficacy for clot resolution in comparison to CDT. We could not
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control for contrast-induced nephropathy (CIN) as a potential cause for AKI because the volume
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was not always included in the operative reports, and was not available to us in the data
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extraction model we had access to. On the other hand, at our institution we only use 270mgI/mL
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Iodixanol for intravascular procedures; and this iodinated contrast agent has the lowest reported
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incidence of CIN given its hypo-osmolar, non-ionic properties. We are also encouraged that this
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alone is unlikely to account for the large difference, as we studied the outcomes in two groups of
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patients who were both treated with endovascular techniques that required exposure to iodinated
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contrast agent. In addition, Angiojet should theoretically reduce contrast exposure by reducing
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the treatment times and the number of contrast boluses needed for the repeated “lysis checks”
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needed in traditional catheter-directed thrombolysis; thus we do not think that contrast exposure
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alone could account for our large difference in odds ratio by multivariable and DAG statistical
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analysis. Finally, rhabdomyolysis from ischemia/reperfusion in some of these cases could
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certainly contribute to a risk of AKI, especially as nearly all of the patients with creatinine
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elevation were treated for arterial thrombus. Unfortunately, only a few patients had myoglobin or
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creatinine kinase levels drawn before and after the lysis procedure. However, rhabdomyolysis
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alone is also unlikely to explain the odds ratio greater than 8 in the AJ group, given that almost
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90% of the control (CDT group) was treated for arterial thrombosis (compared to only 65% of
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AJ), and few patients required amputations or fasciotomies in either group. When we analyzed
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the indication of the procedure (venous thrombolysis or arterial) as a risk factor, we did not find
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any statistically significant difference in the odds of developing AKI, although this is not
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definitive given the smaller numbers involved. If significant rhabdomyolysis alone were the
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predominate cause of this difference, then we would have expected more patients would have
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either had fasciotomies, or subsequent amputations in the AKI group, which was not found.
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Nevertheless, we certainly acknowledge that we cannot exclude this as a contributing factor in
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this retrospective review.
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In summary, AJ significantly increases the odds of renal injury when compared to CDT and is known to cause hemolysis. AJ has been directly linked to dialysis-dependent renal failure
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in at least one large registry and in one published case report. We believe that hemolysis is not
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benign to the kidney either acutely or chronically, and patients treated for recurrent thrombotic
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syndromes may be at higher risk to both. Further study being done at our institution to better
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identify other causal risk factors (Angiojet treatment times, time intervals between treatments,
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duration of hematuria post-procedure, improved quantification of blood loss etc.) so as to better
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define the ideal patients and techniques to optimally use AJ for acute intravascular thrombosis.
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Figure 1
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A) Panel A (left) shows gross hematuria being collected in a urine collection tubing
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B) Demonstrates the progression of hematuria from normal, clear urine prior to Angiojet (black arrow), followed by the progressively denser hematuria (white arrow).
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Figure 2
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Raw incidence of acute kidney injury (AKI) defined as an increase greater than 25% of baseline.
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(Angiojet = AJ, Catheter directed thrombolysis = CDT, Creatinine= Cr)
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Percent change in the creatinine in treated patients when exposed to additional open surgery.
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Dotted horizontal line indicates the threshold for definition of acute kidney injury (25% rise after
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the procedure). (Angiojet = AJ, Catheter directed thrombolysis =CDT)
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Figure 4
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Graph showing the effect of a drop in the hematocrit (as a percentage of baseline) after being
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treated with Angiojet (AJ) or catheter directed thrombolysis (CDT), in those that did, or did not
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have acute kidney injury (AKI).
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Figure 5
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Univariable analysis and forest plot to demonstrate Odds Ratios (OR) and 95% confidence
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intervals (CI) of variables expected to be related to development of AKI. Odds ratio axis is at a
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Log 5 scale. (Angiojet = AJ, Major open surgical procedures = Maj Surg, Chronic renal failure =
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CRF, patients with at least a 10% drop in their hematocrit = 10% Drop HCT)
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398 Figure 6
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Multivariable logistic regression analysis and forest plot to demonstrate Odds Ratios (OR) and
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95% confidence intervals (CI) of variables expected to be related to development of AKI. Odds
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ratio axis is at a Log 5 scale. (Angiojet = AJ, Major open surgical procedures = Maj Surg,
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Chronic renal failure = CRF, patients with at least a 10% drop in their hematocrit = 10% Drop
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HCT)
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405 Figure 7
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Directed acyclic graphs (DAGs) using DAGitty software to determine the potential effects of
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each variable. The graph was created by the authors using background knowledge of potential
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interactions between the variables involved with lysis and developing AKI.
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Lysis procedure is the primary exposure and acute kidney injury (AKI) is the outcome. Red
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variables are potential confounders to the “total effect” of the lysis procedure on AKI, as they
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potentially influence both the primary exposure and AKI. Blue variables are those that may bias
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the “direct effect” of lysis procedure as they alone can cause AKI independently of the lysis
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procedure. Green variables are determinants to the Lysis and do not directly affect AKI. (Arterial
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thrombosis = Arterial_clot, Venous thrombosis = venous clot, Chronic renal failure = CRF,
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Diabetes mellitus = DM, Drop in hematocrit = Drop_Hematocrit)
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Table 1
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Patient baseline demographics comorbidities and lab values for angiojet patients and catheter-
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directed thrombolysis (CDT) patients. (Cr=Creatinine mg/dL, HCT= hematocrit, not significant
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= NS).
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Table 2
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Adjunct endovascular and surgical procedures done to each group
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