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Duplex Ultrasound for Diagnosis of Failing Stents Placed for Lower Extremity Arterial Occlusive Disease
Journal Pre-proof Duplex ultrasound for diagnosis of failing stents placed for lower extremity arterial occlusive disease Hong Zheng, DO, Keith D. Calligaro, MD, Jiah Jang, DO, Samuel Tyagi, MD, Nicholas Madden, DO, Douglas A. Troutman, DO, Matthew J. Dougherty, MD PII:
S0890-5096(19)30765-4
DOI:
https://doi.org/10.1016/j.avsg.2019.08.086
Reference:
AVSG 4628
To appear in:
Annals of Vascular Surgery
Received Date: 22 August 2018 Revised Date:
1 August 2019
Accepted Date: 11 August 2019
Please cite this article as: Zheng H, Calligaro KD, Jang J, Tyagi S, Madden N, Troutman DA, Dougherty MJ, Duplex ultrasound for diagnosis of failing stents placed for lower extremity arterial occlusive disease, Annals of Vascular Surgery (2019), doi: https://doi.org/10.1016/j.avsg.2019.08.086. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. 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. © 2019 Elsevier Inc. All rights reserved.
1
Duplex ultrasound for diagnosis of failing stents
2
placed for lower extremity arterial occlusive disease
3 4 5 6
Hong Zheng, DO, Keith D. Calligaro, MD, Jiah Jang, DO, Samuel Tyagi, MD, Nicholas
7
Madden, DO, Douglas A. Troutman, DO, and Matthew J. Dougherty, MD
8 9 10 11 12
Presented at the Society for Clinical Vascular Surgery.
13
Las Vegas, NV. March 18, 2018.
14
ABSTRACT
15
Objective: Non-invasive diagnostic testing may be beneficial to identify stenotic (failing) stents
16
placed for occlusive lower extremity peripheral arterial disease (LEPAD), especially if
17
subsequent intervention proves useful in maintaining prolonged stent patency. We previously
18
documented the benefit of surveillance duplex ultrasonography (DU) for peripheral covered
19
stents (stent grafts). The purpose of this study was to evaluate whether DU can reliably diagnose
20
failing bare metal stents placed in iliac, femoral and popliteal arteries for LEPAD.
21
Methods: Between January 1, 2013 – December 31, 2016, 172 stents were placed for LEPAD in
22
119 arterial segments (1.4 stents/stenotic artery) in 110 patients who underwent one or more DU
23
surveillance study documenting stent patency. Post-stent DU surveillance was performed in our
24
Inter-societal Accreditation Commission accredited non-invasive vascular lab at one week and
25
then every six months. DU measured peak systolic velocities (PSVs) and ratio of adjacent PSVs
26
(Vr) every 2.0 cm within the stent(s) and adjacent arteries. We retrospectively classified the
27
following factors as “abnormal DU findings”: focal PSVs > 300 cm/s, uniform PSVs < 45 cm/s,
28
and Vr > 3.0.
29
Results: During average follow-up of 22 months (range, 1 week - 48 months), all three of these
30
DU criteria were “normal” in 62 (52%) of the 119 stented segments. Of the other 57 (48%)
31
stented arterial segments that had one or more abnormal DU finding, 40 underwent prophylactic
32
intervention, 12 patients did not undergo intervention and subsequently occluded (5 patient
33
refusal, 4 surgeon-decision, 3 shortened surveillance interval), and 5 remained patent after mean
34
follow-up of 7.2 months. Of the 12 arterial segments that occluded, 6 patients chose not to have
35
further intervention, 4 failed additional endovascular intervention and required an arterial bypass,
36
and 2 required amputation. Therefore, of the 17 stented arterial segments with one or more
37
abnormal DU finding that did not undergo intervention, 12 (70%) went on to occlude vs. 2 of 62
38
(3%) with normal DU findings demonstrating an odds ratio (OR) of 72.0 (95% CI 12.5 – 415.6,
39
P < 0.0001). Of these 12 stented arterial segments with abnormal DU findings that occluded, 7
40
had uniform low PSVs alone, 3 had both abnormal PSV and Vr’s, and 2 had abnormal Vr’s
41
alone.
42
Conclusion: DU surveillance can predict LEPAD stent occlusion. While PSV > 300cm/sec
43
alone is not a statistically significant predictor of stent failure, Vr > 3.0, and most importantly,
44
uniform PSVs < 45 cm/s throughout the stent were statistically reliable markers for predicting
45
stent thrombosis, while the absence of any of these abnormalities strongly predicted stent
46
patency.
47 48
49 50
Introduction As endovascular technologies grow, an increasing number of patients with lower
51
extremity peripheral arterial disease (LEPAD) are being treated with balloon angioplasty,
52
stenting or other endovascular adjuncts. Bare metal stents continue to be widely used in the
53
treatment of ilio-femoral and femoro-popliteal occlusive disease. Duplex ultrasound (DU)
54
surveillance has been suggested to improve patency rates of lower extremity vein and prosthetic
55
bypasses by identifying and prophylactically treating failing grafts. 1-5 Although Baril et al
56
demonstrated a correlation between DU criteria and angiographic evidence of significant in-stent
57
stenosis in superficial femoral arteries6, the value of DU surveillance to identify failing or
58
stenotic peripheral stents remains controversial. The purpose of this study was to determine
59
whether DU criteria can predict failure of bare metal stents placed in iliac and femoro-popliteal
60
arteries.
61 62 63 64
Methods
65
LEPAD by vascular surgeons at Pennsylvania Hospital between January 1, 2013 and December
66
31, 2016 were reviewed. All patients had at least one DU surveillance study documenting stent
67
patency. The post-stent DU surveillance protocol included studies performed in our Inter-
68
societal Accreditation Commission (IAC) accredited non-invasive vascular lab at one week post-
69
intervention and then every three to six months. DU was performed with the patient in the supine
70
position. Imaging was performed from the inflow artery to the outflow artery involving the
71
arterial segment treated with stents. The arteries were measured in the transverse and
72
longitudinal axes. DU measurements were performed every 2.0 cm within the stent(s) and
Patients treated with bare metal stents placed in the iliac and femoro-popliteal arteries for
73
adjacent arteries with B-mode imaging and spectral doppler. DU was performed by registered
74
vascular laboratory technologists using version 6.3.5.7 software (Philips HD-11, Phillips DHI-
75
5000, Philips HDI-3000; Bothell, WA). Patient studies were prospectively maintained in a
76
computer database (Access, Microsoft Corp, Redmond CA). Odds ratio calculations were
77
performed to compare the group who had abnormal duplex ultrasound and did not receive
78
reintervention (the ‘exposed’ group) to the normal duplex ultrasound group (the ‘unexposed’
79
group). Patient consent and Institutional Review Board approval were not obtained due to use of
80
a de-identified database.
81
DU parameters measured included peak systolic velocities (PSVs), the ratio of adjacent
82
PSVs (Vr), and the luminal diameter of the stent and adjacent artery. We classified the following
83
factors as “abnormal” DU findings: focal PSVs > 300 cm/s, uniform PSVs < 45 cm/s throughout
84
the stented segment, or a Vr > 3.0, based on previously published criteria for failing lower
85
extremity bypass grafts and stent grafts (1-6). Studies with none of the DU findings were
86
classified as “normal”.
87 88 89 90
Results
One-hundred seventy-two stents were placed for LEPAD in 119 arterial segments (1.4
91
stents/stenotic artery) in 110 patients and 116 limbs who underwent more than one DU
92
surveillance study documenting stent patency. There were 77 LifeStent (C. R. Bard Inc, Temple,
93
AZ) (45%), 43 Epic (Boston Scientific, Natick, MA) (25%), 26 Luminexx (C. R. Bard Inc,
94
Temple, AZ) (15%), 12 Supera (Abbott, Abbott Park, IL) (7%), 10 Wallstent (Boston Scientific,
95
Natick, MA) (6%), and 4 Protégé Everflex (Medtronic, Minneapolis, MN) (2%) stents inserted in
96
30 iliac and 89 femoro-popliteal arteries. Mean treatment length was 7.5 cm in iliac arteries
97
(range, 4.0 – 15.0 cm) and 12.2 cm in femoro-popliteal arteries (range, 2.0 - 21.0 cm). Mean
98
follow-up was 22 months (range, 1 week - 48 months).
99 100
Patients were classified according to presenting symptoms using the Rutherford
101
Classification for chronic ischemia (Table I). The majority of limbs treated were for Rutherford
102
classification 3-5 (severe claudication to minor tissue loss).
103 104
Of the 119 stented segments, 62 (52%) had “normal” DU criteria, without any of the
105
three abnormal criteria. During follow-up 60 remained patent and two occluded. One occlusion
106
was treated with a stent graft and the other failed endovascular re-intervention and required an
107
arterial bypass for rest pain. The other 57 (48%) stented arterial segments had one or more
108
“abnormal” DU finding: 40 underwent prophylactic intervention and remained patent with
109
normal DU on subsequent follow-up. All 40 of these patients demonstrated a hemodynamically
110
significant lesion at arteriography. This was treated either by scoring balloon or drug-coated
111
balloon angioplasty and selective atherectomy of native lesions, with new stent placement if
112
there was greater than50% residual stenosis following this initial intervention. Twelve patients
113
with abnormal duplex findings did not have reintervention and occluded while 5 did not have
114
reintervention and remained patent at mean follow-up of 7.2 months. Of the 12 patients who did
115
not have reintervention, 5 patients refused, and in 7 patients intervention was deferred in favor of
116
a shortened surveillance interval of three months.
117
Of these 12 arterial segments that occluded with “abnormal” DU findings, 6 patients
118
chose no further intervention and remained with claudication only, 4 failed additional
119
endovascular intervention and required an arterial bypass, and 2 required amputation. Therefore,
120
12 (70%) of the 17 stented arterial segments with one or more “abnormal” DU finding that did
121
not undergo intervention progressed to occlusion vs. 2 of 62 (3%) with “normal” DU findings
122
(Table II). Of these 12 stented arterial segments with abnormal DU findings that occluded, 7 had
123
uniform low PSVs only, 3 had both abnormal elevated PSV > 300cm/sec and Vr, and 2 had
124
abnormal Vr only (Table III). A total of 14 stents occluded. The mean time to occlusion was 5.6
125
months (95% confidence interval 4.3 – 6.9).
126
We performed a standard odds ratio (OR) calculation, comparing the odds of stent
127
thrombosis between the abnormal and normal duplex groups. This calculation was done by
128
dividing the product of the thrombosed stents in the abnormal duplex group and the open stents
129
in the normal duplex group by the product of the open stents in the abnormal duplex group and
130
the thrombosed stents in the normal duplex group. Evaluating for the presence of any abnormal
131
duplex criteria, we found an Odds Ratio of 72.0 (95% CI 12.5 – 415.6, P < 0.0001). We then
132
looked at each individual criterion. We did include patients in the abnormal group which did not
133
have that specific criteria in the control group for these calculations (for example, patients with
134
uniform PSV < 45cm/sec were included in the control group when analyzing patients with PSV
135
> 300cm/sec, etc). For PSV > 300cm/sec the OR is 4.2 (95% CI 0.8 – 21.2, P = 0.08). For Vr >
136
3.0 the OR is 11.5 (95% CI 2.3 – 56.5, P = 0.0027) and for uniform PSV < 45cm/sec the OR is
137
64.0 (95% CI 6.8 – 598.7, P = 0.0003). Combination of PSV > 300cm/sec and Vr > 3.0 had OR
138
of 5.6 (95% CI 1.0 – 31.6, P = 0.0493). This suggests uniform PSVs < 45 cm/sec was the most
139
accurate predictor of stent failure.
140 141 142 143
Discussion The incidence of re-stenosis and occlusion following endovascular interventions for
144
LEPAD has been reported to be as high as 40% after one year.7 With increasing use of stents to
145
treat LEPAD, DU surveillance may prove useful to help maintain patency of these
146
revascularizations should they develop stenotic lesions. However, there are conflicting
147
recommendations in the literature whether this strategy is worthwhile.
148
DU surveillance has been widely accepted for lower extremity vein bypass grafts to
149
detect lesions that may lead to graft failure. It is less accepted for prosthetic bypasses, and there
150
is currently limited evidence for its use in peripheral arterial stents. Intimal hyperplasia is most
151
likely to develop during the first two years after lower extremity vein bypass grafts, hence the
152
SVS Guidelines for DU vein graft surveillance recommending studies every three months for the
153
first year, every six months for the next year, and annually thereafter. There are no established
154
guidelines for peripheral arterial stent DU surveillance. While bypass graft failure is frequently
155
associated with a need for more complex treatment and poor outcomes, this may not be the case
156
for bare metal stent thrombosis.
157
Tielbeek et al described similar sensitivity and specificity for peripheral stent surveillance
158
using DU surveillance compared to following patients with only symptomatic and ankle-brachial
159
index (ABI) changes.9 Bui et al also reported that DU surveillance may not be worthwhile since
160
DU predicted occlusion with a sensitivity and specificity of only 88% and 60%, respectively.10
161
Conversely, Kinney et al have shown that ABI alone is insufficient to distinguish
162
recurrent stent stenosis vs. progression of atherosclerotic disease in untreated areas. 11 Baril and
163
associates from the University of Pittsburgh identified DU criteria to detect in-stent re-stenosis in
164
the superficial femoral artery and support its use.6 This group used PSVs and Vr to determine DU
165
criteria that was both sensitive and specific for in-stent re-stenosis of the femoro-popliteal artery.
166
They concluded that a PSV > 275 cm/sec or a Vr > 3.5 was highly specific and predictive of
167
80% or more in-stent stenosis. A review of the literature by Shames suggested that routine post-
168
operative DU surveillance of lower extremity stents may help to improve primary assisted
169
patency rate to 80% at one year.7 Finally, a recent Reporting Standards document by the Society
170
for Vascular Surgery for endovascular treatment of chronic LEPAD recommended DU imaging
171
as the standard for lower extremity endovascular surveillance. 12 Studies were recommended to
172
be performed in an accredited non-invasive vascular laboratory one week after the endovascular
173
intervention, every three months the first year, and every six months or annually thereafter.12
174
We have previously described the utility of DU for surveillance of lower extremity stent
175
grafts (covered stents) placed for peripheral arterial disease.13 In our current retrospective
176
analysis of peripheral stent surveillance, we applied similar criteria to diagnose a failing (or
177
stenotic) peripheral stent. We defined “abnormal DU findings” as a focal PSV > 300 cm/sec,
178
uniform PSVs < 45 cm/sec, or Vr > 3.0. When taken together the odds ratio (OR) for stent
179
thrombosis with any positive duplex finding is 72.0. When evaluated independently, PSV >
180
300cm/sec alone is not a significant predictor with OR of 4.2 (95% CI 0.8 – 21.2, P = 0.08).
181
While Vr > 3.0 and uniform PSV < 45cm/sec are both predictors of stent failure, uniform PSV <
182
45cm/sec is the strongest predictor for stent thrombosis with an OR of 64.0 and 95% CI from 6.8
183
– 598.7.
184
We included a life-table (Graph I) evaluating the percentage of stents remaining patent in
185
the three different groups of our study which demonstrates the significantly increased risk of a
186
thrombotic complication in the patients with these abnormal findings.
187
If reliable DU criteria are established to predict a failing peripheral arterial stent, the
188
question remains whether subsequent prophylactic treatment of these stenotic lesions prior to
189
onset of symptoms or stent occlusion is worthwhile. There are several advantages of intervening
190
before symptoms develop or stents occlude. First, onset of symptoms is commonly associated
191
with stent occlusion and not just stent stenosis, similar to the reasoning for intervention of failing
192
lower extremity vein bypasses prior to onset of symptoms. Technical success is higher when
193
treating a stenotic stent than an occluded one, especially for a long occlusion. A stent placed for
194
claudication that acutely occludes may result in thrombosis of important collaterals with an
195
associated limb-threatening situation. Thrombolysis may prove necessary to salvage an occluded
196
stent, especially if distal small arteries have also occluded, and has associated morbidity and
197
extra cost. Restoring patency of an occluded stent may be associated with an increased likelihood
198
of distal embolization compared to balloon angioplasty of a stenotic but patent stent that is not
199
filled with thrombus. Lastly, similar to lower extremity bypasses, subsequent patency of a failing
200
but patent stent may be higher than patency of a stent that has already occluded.
201
There are several limitations of this study. These results were based on findings reported
202
by highly skilled technologists in an IAC-accredited non-invasive vascular laboratory that is
203
devoted to vascular duplex surveillance studies. Other vascular labs may not yield the same
204
results. Peripheral stents placed in iliac, femoral and popliteal arteries were analyzed in this
205
study, so recommendations cannot be made regarding tibial stents. Our series had a relatively
206
small sample size. Additionally, our database did not include data regarding demographics,
207
comorbidities or complete TASC classification data and there exists a possibility of a
208
confounding variable explaining our findings. Lastly, DU surveillance of stents may also be
209
limited by the patient’s habitus, dense calcifications, or prior surgeries.
210
Follow-up studies based on this information could include prospective or randomized
211
trials evaluating the natural history and effect of intervention on abnormal duplex findings
212
following peripheral arterial stenting.
213 214 215
Conclusion
216
Our results suggest that DU surveillance can predict LEPAD stent thrombosis. Focal
217
PSVs > 300 cm/s, Vr > 3.0, and most importantly, uniform PSVs < 45 cm/s throughout the stent
218
were statistically reliable markers for predicting stent thrombosis, while the absence of any of
219
these abnormalities strongly predicted stent patency.
220
221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266
REFERENCES 1. Calligaro KD, Syrek JR, Dougherty MD, Rua I, McAffee-Bennett S, Doerr KJ et al. Selective use of duplex ultrasound to replace preoperative arteriography for failing arterial vein grafts. J Vasc Surg 1998;27:89-95. 2. Calligaro KD, Musser DJ, Chen AY, Dougherty MD, McAffee-Bennett S, Doerr KJ et al. Duplex ultrasonography to diagnose failing arterial prosthetic grafts. Surgery 1996;120:455-59. 3. Calligaro KD, Doerr K, McAffee-Bennett S, Krug R, Raviola CA, Dougherty MD. Should duplex ultrasonography be performed for surveillance of femoropopliteal and femorotibial arterial prosthetic bypass? Ann Vasc Surg 2001;15:520-24. 4. Bandyk DF, Schmitt DD, Seabrook GR, Adams MB, Towne JB. Monitoring functional patency of in situ saphenous vein bypasses: The impact of a surveillance protocol and elective revision. J Vasc Surg 1989:9:286-96. 5. Mills JL, Harris EJ, Taylor LM, Beckett WC, Porter JM. The importance of routine surveillance of distal bypass grafts with duplex scanning: A study of 379 reversed vein grafts. J Vasc Surg 1990;12:379-89. 6. Baril DT, Rhee RY, Kim J, Makaroun MS, Chaer RA, Marone LK. Duplex criteria for determination of in-stent stenosis after angioplasty and stenting of the superficial femoral artery. J Vasc Surg 2009;49:133-39. 7. Shames ML. Duplex surveillance of lower extremity endovascular interventions. Perspect Vasc Surg Endovasc Ther 2007;19:370-374 8. Conte MS, Pomposelli FB, Clair DG, Geraghty PJ, McKinsey JF, Mills JL, Moneta GL, Murad MH, Powell RJ, Reed AB, Schanzer A, Sidawy A. Society for Vascular Surgery practice guidelines for atherosclerotic occlusive disease of the lower extremities: management of asymptomatic disease and claudication. J Vasc Surg 2015;61:2Se41S. 9. Tielbeek AV, Rietjens E, Buth J, Vroegindeweij D, Schol FPG. The value of duplex surveillance after endovascular intervention for femoropopliteal obstructive disease. Eur J Vasc Endovasc Surg 1996; 12:145-150 10. Bui TD, Mills JL, Ihnat DM, Gruessner AC, Goshima KR, Hughes JD. The nature history of duplex-detected stenosis after femoropopliteal endovascular therapy suggests questionable clinical utility of routine duplex surveillance. J Vasc Surg 2012;55:346-52 11. Kinney EV, Bandyk DF, Mewissen MW, Lanza D, Bergamini TM, Lipchik EO, Seabrook GR, Towne JB. Monitoring functional patency of percutaneous transluminal angioplasty. Arch Surg. 1991;126(6):743-747 12. Stoner MC, Calligaro KD, Chaer RA, Dietzek AM, Farber A, Guzman RJ, Hamdan AD, Landry GJ, Yamaguchi DJ on behalf of the SVS. Reporting standards of the Society for Vascular surgery for endovascular treatment of chronic lower extremity peripheral artery disease. J Vasc Surg 2016;64:e1-e-21 13. Troutman DA, Madden NJ, Dougherty MJ, Calligaro KD. Duplex ultrasound diagnosis of failing stent grafts placed for occlusive disease. J Vasc Surg 2014;60;1580-1584
267 268 269 270
Table I Clinical Symptoms for patients treated with peripheral artery stents Rutherford Classification 1 2 3 4 5 6
Iliac
Femoro-popliteal
4 18 5 3 3
6 51 20 11 -
271 272
Table II
273
Stent patency based on normal versus abnormal Duplex Ultrasound (DU) criteria Total Cohort
274 275 276 277 278 279 280
281 282
Abnormal DU
Normal DU
Total
Occluded
12
2
14
Patent
5
60
65
Total
17
62
79
Table III Duplex ultrasound (DU) criteria characteristics for occluded stents
DU criteria PSV > 300cm/s alone Vr > 3.0 alone Uniform PSV < 45cm/s (low flow) PSV > 300cm/s + Vr > 3.0
N 0 2 7 3
Total
12
DU, Duplex Ultrasound; PSV, Peak Systolic Velocity; Vr, Velocity Ratio
283 284
Table IV Abnormal DU Criteria in stents which did not occlude DU Criteria PSV > 300cm/s alone Vr > 3.0 alone Uniform PSV < 45cm/s PSV > 300cm/s and Vr > 3.0 Total
285 286 287 288 289
290 291 292 293
DU, Duplex Ultrasound; PSV, Peak Systolic Velocity; Vr, Velocity Ratio
Figure I Life Table Demonstrated as Percent (%) Stent Patency over Time
Table V Patients at risk for each time period
Months
Normal 0 3 6 9 12 15 18
294 295 296
N 1 0 1 3 5
62 60 58 58 57 57 57
Abnormal Duplex + Intervention
Abnormal Duplex + Observation 40 40 39 39 38 38 38
17 15 7 3 3 2 2
S0890-5096(19)30765-4
DOI:
https://doi.org/10.1016/j.avsg.2019.08.086
Reference:
AVSG 4628
To appear in:
Annals of Vascular Surgery
Received Date: 22 August 2018 Revised Date:
1 August 2019
Accepted Date: 11 August 2019
Please cite this article as: Zheng H, Calligaro KD, Jang J, Tyagi S, Madden N, Troutman DA, Dougherty MJ, Duplex ultrasound for diagnosis of failing stents placed for lower extremity arterial occlusive disease, Annals of Vascular Surgery (2019), doi: https://doi.org/10.1016/j.avsg.2019.08.086. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. 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. © 2019 Elsevier Inc. All rights reserved.
1
Duplex ultrasound for diagnosis of failing stents
2
placed for lower extremity arterial occlusive disease
3 4 5 6
Hong Zheng, DO, Keith D. Calligaro, MD, Jiah Jang, DO, Samuel Tyagi, MD, Nicholas
7
Madden, DO, Douglas A. Troutman, DO, and Matthew J. Dougherty, MD
8 9 10 11 12
Presented at the Society for Clinical Vascular Surgery.
13
Las Vegas, NV. March 18, 2018.
14
ABSTRACT
15
Objective: Non-invasive diagnostic testing may be beneficial to identify stenotic (failing) stents
16
placed for occlusive lower extremity peripheral arterial disease (LEPAD), especially if
17
subsequent intervention proves useful in maintaining prolonged stent patency. We previously
18
documented the benefit of surveillance duplex ultrasonography (DU) for peripheral covered
19
stents (stent grafts). The purpose of this study was to evaluate whether DU can reliably diagnose
20
failing bare metal stents placed in iliac, femoral and popliteal arteries for LEPAD.
21
Methods: Between January 1, 2013 – December 31, 2016, 172 stents were placed for LEPAD in
22
119 arterial segments (1.4 stents/stenotic artery) in 110 patients who underwent one or more DU
23
surveillance study documenting stent patency. Post-stent DU surveillance was performed in our
24
Inter-societal Accreditation Commission accredited non-invasive vascular lab at one week and
25
then every six months. DU measured peak systolic velocities (PSVs) and ratio of adjacent PSVs
26
(Vr) every 2.0 cm within the stent(s) and adjacent arteries. We retrospectively classified the
27
following factors as “abnormal DU findings”: focal PSVs > 300 cm/s, uniform PSVs < 45 cm/s,
28
and Vr > 3.0.
29
Results: During average follow-up of 22 months (range, 1 week - 48 months), all three of these
30
DU criteria were “normal” in 62 (52%) of the 119 stented segments. Of the other 57 (48%)
31
stented arterial segments that had one or more abnormal DU finding, 40 underwent prophylactic
32
intervention, 12 patients did not undergo intervention and subsequently occluded (5 patient
33
refusal, 4 surgeon-decision, 3 shortened surveillance interval), and 5 remained patent after mean
34
follow-up of 7.2 months. Of the 12 arterial segments that occluded, 6 patients chose not to have
35
further intervention, 4 failed additional endovascular intervention and required an arterial bypass,
36
and 2 required amputation. Therefore, of the 17 stented arterial segments with one or more
37
abnormal DU finding that did not undergo intervention, 12 (70%) went on to occlude vs. 2 of 62
38
(3%) with normal DU findings demonstrating an odds ratio (OR) of 72.0 (95% CI 12.5 – 415.6,
39
P < 0.0001). Of these 12 stented arterial segments with abnormal DU findings that occluded, 7
40
had uniform low PSVs alone, 3 had both abnormal PSV and Vr’s, and 2 had abnormal Vr’s
41
alone.
42
Conclusion: DU surveillance can predict LEPAD stent occlusion. While PSV > 300cm/sec
43
alone is not a statistically significant predictor of stent failure, Vr > 3.0, and most importantly,
44
uniform PSVs < 45 cm/s throughout the stent were statistically reliable markers for predicting
45
stent thrombosis, while the absence of any of these abnormalities strongly predicted stent
46
patency.
47 48
49 50
Introduction As endovascular technologies grow, an increasing number of patients with lower
51
extremity peripheral arterial disease (LEPAD) are being treated with balloon angioplasty,
52
stenting or other endovascular adjuncts. Bare metal stents continue to be widely used in the
53
treatment of ilio-femoral and femoro-popliteal occlusive disease. Duplex ultrasound (DU)
54
surveillance has been suggested to improve patency rates of lower extremity vein and prosthetic
55
bypasses by identifying and prophylactically treating failing grafts. 1-5 Although Baril et al
56
demonstrated a correlation between DU criteria and angiographic evidence of significant in-stent
57
stenosis in superficial femoral arteries6, the value of DU surveillance to identify failing or
58
stenotic peripheral stents remains controversial. The purpose of this study was to determine
59
whether DU criteria can predict failure of bare metal stents placed in iliac and femoro-popliteal
60
arteries.
61 62 63 64
Methods
65
LEPAD by vascular surgeons at Pennsylvania Hospital between January 1, 2013 and December
66
31, 2016 were reviewed. All patients had at least one DU surveillance study documenting stent
67
patency. The post-stent DU surveillance protocol included studies performed in our Inter-
68
societal Accreditation Commission (IAC) accredited non-invasive vascular lab at one week post-
69
intervention and then every three to six months. DU was performed with the patient in the supine
70
position. Imaging was performed from the inflow artery to the outflow artery involving the
71
arterial segment treated with stents. The arteries were measured in the transverse and
72
longitudinal axes. DU measurements were performed every 2.0 cm within the stent(s) and
Patients treated with bare metal stents placed in the iliac and femoro-popliteal arteries for
73
adjacent arteries with B-mode imaging and spectral doppler. DU was performed by registered
74
vascular laboratory technologists using version 6.3.5.7 software (Philips HD-11, Phillips DHI-
75
5000, Philips HDI-3000; Bothell, WA). Patient studies were prospectively maintained in a
76
computer database (Access, Microsoft Corp, Redmond CA). Odds ratio calculations were
77
performed to compare the group who had abnormal duplex ultrasound and did not receive
78
reintervention (the ‘exposed’ group) to the normal duplex ultrasound group (the ‘unexposed’
79
group). Patient consent and Institutional Review Board approval were not obtained due to use of
80
a de-identified database.
81
DU parameters measured included peak systolic velocities (PSVs), the ratio of adjacent
82
PSVs (Vr), and the luminal diameter of the stent and adjacent artery. We classified the following
83
factors as “abnormal” DU findings: focal PSVs > 300 cm/s, uniform PSVs < 45 cm/s throughout
84
the stented segment, or a Vr > 3.0, based on previously published criteria for failing lower
85
extremity bypass grafts and stent grafts (1-6). Studies with none of the DU findings were
86
classified as “normal”.
87 88 89 90
Results
One-hundred seventy-two stents were placed for LEPAD in 119 arterial segments (1.4
91
stents/stenotic artery) in 110 patients and 116 limbs who underwent more than one DU
92
surveillance study documenting stent patency. There were 77 LifeStent (C. R. Bard Inc, Temple,
93
AZ) (45%), 43 Epic (Boston Scientific, Natick, MA) (25%), 26 Luminexx (C. R. Bard Inc,
94
Temple, AZ) (15%), 12 Supera (Abbott, Abbott Park, IL) (7%), 10 Wallstent (Boston Scientific,
95
Natick, MA) (6%), and 4 Protégé Everflex (Medtronic, Minneapolis, MN) (2%) stents inserted in
96
30 iliac and 89 femoro-popliteal arteries. Mean treatment length was 7.5 cm in iliac arteries
97
(range, 4.0 – 15.0 cm) and 12.2 cm in femoro-popliteal arteries (range, 2.0 - 21.0 cm). Mean
98
follow-up was 22 months (range, 1 week - 48 months).
99 100
Patients were classified according to presenting symptoms using the Rutherford
101
Classification for chronic ischemia (Table I). The majority of limbs treated were for Rutherford
102
classification 3-5 (severe claudication to minor tissue loss).
103 104
Of the 119 stented segments, 62 (52%) had “normal” DU criteria, without any of the
105
three abnormal criteria. During follow-up 60 remained patent and two occluded. One occlusion
106
was treated with a stent graft and the other failed endovascular re-intervention and required an
107
arterial bypass for rest pain. The other 57 (48%) stented arterial segments had one or more
108
“abnormal” DU finding: 40 underwent prophylactic intervention and remained patent with
109
normal DU on subsequent follow-up. All 40 of these patients demonstrated a hemodynamically
110
significant lesion at arteriography. This was treated either by scoring balloon or drug-coated
111
balloon angioplasty and selective atherectomy of native lesions, with new stent placement if
112
there was greater than50% residual stenosis following this initial intervention. Twelve patients
113
with abnormal duplex findings did not have reintervention and occluded while 5 did not have
114
reintervention and remained patent at mean follow-up of 7.2 months. Of the 12 patients who did
115
not have reintervention, 5 patients refused, and in 7 patients intervention was deferred in favor of
116
a shortened surveillance interval of three months.
117
Of these 12 arterial segments that occluded with “abnormal” DU findings, 6 patients
118
chose no further intervention and remained with claudication only, 4 failed additional
119
endovascular intervention and required an arterial bypass, and 2 required amputation. Therefore,
120
12 (70%) of the 17 stented arterial segments with one or more “abnormal” DU finding that did
121
not undergo intervention progressed to occlusion vs. 2 of 62 (3%) with “normal” DU findings
122
(Table II). Of these 12 stented arterial segments with abnormal DU findings that occluded, 7 had
123
uniform low PSVs only, 3 had both abnormal elevated PSV > 300cm/sec and Vr, and 2 had
124
abnormal Vr only (Table III). A total of 14 stents occluded. The mean time to occlusion was 5.6
125
months (95% confidence interval 4.3 – 6.9).
126
We performed a standard odds ratio (OR) calculation, comparing the odds of stent
127
thrombosis between the abnormal and normal duplex groups. This calculation was done by
128
dividing the product of the thrombosed stents in the abnormal duplex group and the open stents
129
in the normal duplex group by the product of the open stents in the abnormal duplex group and
130
the thrombosed stents in the normal duplex group. Evaluating for the presence of any abnormal
131
duplex criteria, we found an Odds Ratio of 72.0 (95% CI 12.5 – 415.6, P < 0.0001). We then
132
looked at each individual criterion. We did include patients in the abnormal group which did not
133
have that specific criteria in the control group for these calculations (for example, patients with
134
uniform PSV < 45cm/sec were included in the control group when analyzing patients with PSV
135
> 300cm/sec, etc). For PSV > 300cm/sec the OR is 4.2 (95% CI 0.8 – 21.2, P = 0.08). For Vr >
136
3.0 the OR is 11.5 (95% CI 2.3 – 56.5, P = 0.0027) and for uniform PSV < 45cm/sec the OR is
137
64.0 (95% CI 6.8 – 598.7, P = 0.0003). Combination of PSV > 300cm/sec and Vr > 3.0 had OR
138
of 5.6 (95% CI 1.0 – 31.6, P = 0.0493). This suggests uniform PSVs < 45 cm/sec was the most
139
accurate predictor of stent failure.
140 141 142 143
Discussion The incidence of re-stenosis and occlusion following endovascular interventions for
144
LEPAD has been reported to be as high as 40% after one year.7 With increasing use of stents to
145
treat LEPAD, DU surveillance may prove useful to help maintain patency of these
146
revascularizations should they develop stenotic lesions. However, there are conflicting
147
recommendations in the literature whether this strategy is worthwhile.
148
DU surveillance has been widely accepted for lower extremity vein bypass grafts to
149
detect lesions that may lead to graft failure. It is less accepted for prosthetic bypasses, and there
150
is currently limited evidence for its use in peripheral arterial stents. Intimal hyperplasia is most
151
likely to develop during the first two years after lower extremity vein bypass grafts, hence the
152
SVS Guidelines for DU vein graft surveillance recommending studies every three months for the
153
first year, every six months for the next year, and annually thereafter. There are no established
154
guidelines for peripheral arterial stent DU surveillance. While bypass graft failure is frequently
155
associated with a need for more complex treatment and poor outcomes, this may not be the case
156
for bare metal stent thrombosis.
157
Tielbeek et al described similar sensitivity and specificity for peripheral stent surveillance
158
using DU surveillance compared to following patients with only symptomatic and ankle-brachial
159
index (ABI) changes.9 Bui et al also reported that DU surveillance may not be worthwhile since
160
DU predicted occlusion with a sensitivity and specificity of only 88% and 60%, respectively.10
161
Conversely, Kinney et al have shown that ABI alone is insufficient to distinguish
162
recurrent stent stenosis vs. progression of atherosclerotic disease in untreated areas. 11 Baril and
163
associates from the University of Pittsburgh identified DU criteria to detect in-stent re-stenosis in
164
the superficial femoral artery and support its use.6 This group used PSVs and Vr to determine DU
165
criteria that was both sensitive and specific for in-stent re-stenosis of the femoro-popliteal artery.
166
They concluded that a PSV > 275 cm/sec or a Vr > 3.5 was highly specific and predictive of
167
80% or more in-stent stenosis. A review of the literature by Shames suggested that routine post-
168
operative DU surveillance of lower extremity stents may help to improve primary assisted
169
patency rate to 80% at one year.7 Finally, a recent Reporting Standards document by the Society
170
for Vascular Surgery for endovascular treatment of chronic LEPAD recommended DU imaging
171
as the standard for lower extremity endovascular surveillance. 12 Studies were recommended to
172
be performed in an accredited non-invasive vascular laboratory one week after the endovascular
173
intervention, every three months the first year, and every six months or annually thereafter.12
174
We have previously described the utility of DU for surveillance of lower extremity stent
175
grafts (covered stents) placed for peripheral arterial disease.13 In our current retrospective
176
analysis of peripheral stent surveillance, we applied similar criteria to diagnose a failing (or
177
stenotic) peripheral stent. We defined “abnormal DU findings” as a focal PSV > 300 cm/sec,
178
uniform PSVs < 45 cm/sec, or Vr > 3.0. When taken together the odds ratio (OR) for stent
179
thrombosis with any positive duplex finding is 72.0. When evaluated independently, PSV >
180
300cm/sec alone is not a significant predictor with OR of 4.2 (95% CI 0.8 – 21.2, P = 0.08).
181
While Vr > 3.0 and uniform PSV < 45cm/sec are both predictors of stent failure, uniform PSV <
182
45cm/sec is the strongest predictor for stent thrombosis with an OR of 64.0 and 95% CI from 6.8
183
– 598.7.
184
We included a life-table (Graph I) evaluating the percentage of stents remaining patent in
185
the three different groups of our study which demonstrates the significantly increased risk of a
186
thrombotic complication in the patients with these abnormal findings.
187
If reliable DU criteria are established to predict a failing peripheral arterial stent, the
188
question remains whether subsequent prophylactic treatment of these stenotic lesions prior to
189
onset of symptoms or stent occlusion is worthwhile. There are several advantages of intervening
190
before symptoms develop or stents occlude. First, onset of symptoms is commonly associated
191
with stent occlusion and not just stent stenosis, similar to the reasoning for intervention of failing
192
lower extremity vein bypasses prior to onset of symptoms. Technical success is higher when
193
treating a stenotic stent than an occluded one, especially for a long occlusion. A stent placed for
194
claudication that acutely occludes may result in thrombosis of important collaterals with an
195
associated limb-threatening situation. Thrombolysis may prove necessary to salvage an occluded
196
stent, especially if distal small arteries have also occluded, and has associated morbidity and
197
extra cost. Restoring patency of an occluded stent may be associated with an increased likelihood
198
of distal embolization compared to balloon angioplasty of a stenotic but patent stent that is not
199
filled with thrombus. Lastly, similar to lower extremity bypasses, subsequent patency of a failing
200
but patent stent may be higher than patency of a stent that has already occluded.
201
There are several limitations of this study. These results were based on findings reported
202
by highly skilled technologists in an IAC-accredited non-invasive vascular laboratory that is
203
devoted to vascular duplex surveillance studies. Other vascular labs may not yield the same
204
results. Peripheral stents placed in iliac, femoral and popliteal arteries were analyzed in this
205
study, so recommendations cannot be made regarding tibial stents. Our series had a relatively
206
small sample size. Additionally, our database did not include data regarding demographics,
207
comorbidities or complete TASC classification data and there exists a possibility of a
208
confounding variable explaining our findings. Lastly, DU surveillance of stents may also be
209
limited by the patient’s habitus, dense calcifications, or prior surgeries.
210
Follow-up studies based on this information could include prospective or randomized
211
trials evaluating the natural history and effect of intervention on abnormal duplex findings
212
following peripheral arterial stenting.
213 214 215
Conclusion
216
Our results suggest that DU surveillance can predict LEPAD stent thrombosis. Focal
217
PSVs > 300 cm/s, Vr > 3.0, and most importantly, uniform PSVs < 45 cm/s throughout the stent
218
were statistically reliable markers for predicting stent thrombosis, while the absence of any of
219
these abnormalities strongly predicted stent patency.
220
221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266
REFERENCES 1. Calligaro KD, Syrek JR, Dougherty MD, Rua I, McAffee-Bennett S, Doerr KJ et al. Selective use of duplex ultrasound to replace preoperative arteriography for failing arterial vein grafts. J Vasc Surg 1998;27:89-95. 2. Calligaro KD, Musser DJ, Chen AY, Dougherty MD, McAffee-Bennett S, Doerr KJ et al. Duplex ultrasonography to diagnose failing arterial prosthetic grafts. Surgery 1996;120:455-59. 3. Calligaro KD, Doerr K, McAffee-Bennett S, Krug R, Raviola CA, Dougherty MD. Should duplex ultrasonography be performed for surveillance of femoropopliteal and femorotibial arterial prosthetic bypass? Ann Vasc Surg 2001;15:520-24. 4. Bandyk DF, Schmitt DD, Seabrook GR, Adams MB, Towne JB. Monitoring functional patency of in situ saphenous vein bypasses: The impact of a surveillance protocol and elective revision. J Vasc Surg 1989:9:286-96. 5. Mills JL, Harris EJ, Taylor LM, Beckett WC, Porter JM. The importance of routine surveillance of distal bypass grafts with duplex scanning: A study of 379 reversed vein grafts. J Vasc Surg 1990;12:379-89. 6. Baril DT, Rhee RY, Kim J, Makaroun MS, Chaer RA, Marone LK. Duplex criteria for determination of in-stent stenosis after angioplasty and stenting of the superficial femoral artery. J Vasc Surg 2009;49:133-39. 7. Shames ML. Duplex surveillance of lower extremity endovascular interventions. Perspect Vasc Surg Endovasc Ther 2007;19:370-374 8. Conte MS, Pomposelli FB, Clair DG, Geraghty PJ, McKinsey JF, Mills JL, Moneta GL, Murad MH, Powell RJ, Reed AB, Schanzer A, Sidawy A. Society for Vascular Surgery practice guidelines for atherosclerotic occlusive disease of the lower extremities: management of asymptomatic disease and claudication. J Vasc Surg 2015;61:2Se41S. 9. Tielbeek AV, Rietjens E, Buth J, Vroegindeweij D, Schol FPG. The value of duplex surveillance after endovascular intervention for femoropopliteal obstructive disease. Eur J Vasc Endovasc Surg 1996; 12:145-150 10. Bui TD, Mills JL, Ihnat DM, Gruessner AC, Goshima KR, Hughes JD. The nature history of duplex-detected stenosis after femoropopliteal endovascular therapy suggests questionable clinical utility of routine duplex surveillance. J Vasc Surg 2012;55:346-52 11. Kinney EV, Bandyk DF, Mewissen MW, Lanza D, Bergamini TM, Lipchik EO, Seabrook GR, Towne JB. Monitoring functional patency of percutaneous transluminal angioplasty. Arch Surg. 1991;126(6):743-747 12. Stoner MC, Calligaro KD, Chaer RA, Dietzek AM, Farber A, Guzman RJ, Hamdan AD, Landry GJ, Yamaguchi DJ on behalf of the SVS. Reporting standards of the Society for Vascular surgery for endovascular treatment of chronic lower extremity peripheral artery disease. J Vasc Surg 2016;64:e1-e-21 13. Troutman DA, Madden NJ, Dougherty MJ, Calligaro KD. Duplex ultrasound diagnosis of failing stent grafts placed for occlusive disease. J Vasc Surg 2014;60;1580-1584
267 268 269 270
Table I Clinical Symptoms for patients treated with peripheral artery stents Rutherford Classification 1 2 3 4 5 6
Iliac
Femoro-popliteal
4 18 5 3 3
6 51 20 11 -
271 272
Table II
273
Stent patency based on normal versus abnormal Duplex Ultrasound (DU) criteria Total Cohort
274 275 276 277 278 279 280
281 282
Abnormal DU
Normal DU
Total
Occluded
12
2
14
Patent
5
60
65
Total
17
62
79
Table III Duplex ultrasound (DU) criteria characteristics for occluded stents
DU criteria PSV > 300cm/s alone Vr > 3.0 alone Uniform PSV < 45cm/s (low flow) PSV > 300cm/s + Vr > 3.0
N 0 2 7 3
Total
12
DU, Duplex Ultrasound; PSV, Peak Systolic Velocity; Vr, Velocity Ratio
283 284
Table IV Abnormal DU Criteria in stents which did not occlude DU Criteria PSV > 300cm/s alone Vr > 3.0 alone Uniform PSV < 45cm/s PSV > 300cm/s and Vr > 3.0 Total
285 286 287 288 289
290 291 292 293
DU, Duplex Ultrasound; PSV, Peak Systolic Velocity; Vr, Velocity Ratio
Figure I Life Table Demonstrated as Percent (%) Stent Patency over Time
Table V Patients at risk for each time period
Months
Normal 0 3 6 9 12 15 18
294 295 296
N 1 0 1 3 5
62 60 58 58 57 57 57
Abnormal Duplex + Intervention
Abnormal Duplex + Observation 40 40 39 39 38 38 38
17 15 7 3 3 2 2