| Research Article |
Open Access |
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| Does Peripheral Neuropathy Have a Clinical Impact on the Endovascular
Approach as a Primary Treatment for Limb-Threatening Ischemic Foot
Wounds in Diabetic Patients? |
| Alexandrescu V1* and Hubermont G2 |
| 1Department of Vascular Surgery, Princess Paola Hospital, Marche-en-Famenne, Belgium |
| 2Department of Diabetology, Princess Paola Hospital, Marche-en-Famenne, Belgium |
| *Corresponding author: |
Alexandrescu V
Department of Vascular Surgery
Princess Paola Hospital
Marche- en-Famenne, Belgium
E-mail: v.alex@skynet.be |
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| Received November 01, 2011; Accepted January 18, 2012; Published January
24, 2012 |
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| Citation: Alexandrescu V, Hubermont G (2012) Does Peripheral Neuropathy
Have a Clinical Impact on the Endovascular Approach as a Primary Treatment for
Limb-Threatening Ischemic Foot Wounds in Diabetic Patients? J Diabetes Metab
S5:006. doi:10.4172/2155-6156.S5-006 |
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| Copyright: © 2012 Alexandrescu V, et al. This is an open-access article distributed
under the terms of the Creative Commons Attribution License, which permits
unrestricted use, distribution, and reproduction in any medium, provided the
original author and source are credited. |
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| Introduction |
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| Approximately 15% of diabetic patients will develop a foot ulcer
during their lifetime and among them, 14% to 43% will require
amputation [1-3]. Peripheral neuropathy, such as chronic inferior limb
ischemia, is a common complication of diabetes mellitus, affecting
approximately 60% of diabetic patients and up to 80% of diabetic
patients with foot ulcers [1-4]. Although the neuropathic etiology is
dominant in 45% of diabetic foot ulcers, both ischemic and neuropathic
risk factors are found in up to 35% of cases [1-4] Current clinical
management, focused on the endovascular approach as a primary
treatment for critical limb ischemia (CLI), is highly feasible and shows
low complication rates [5,6] and limb salvage rates comparable to
surgery [5-8]. Although diabetic neuropathy has already been reported
as an important risk factor for limb loss independently from limbthreatening
ischemia, [1-4] there is little information on its direct effect
on the outcome after surgical and endovascular reconstruction. Thus,
the aim of the present study was to analyze the effect of concomitant
peripheral neuropathy on critical limb ischemia in diabetic patients
initially treated by endovascular methods. A retrospective design was
used to assess clinical outcome in diabetic patients with ischemic foot
wounds with and without concomitant peripheral neuropathy. |
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| Materials and Methods |
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| Patients |
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| Between January 2005 and November 2010, below-the-knee
(BTK) angioplasty was performed on a total of 152 ischemic limbs
of 140 diabetic patients as a primary treatment for critical ischemic
ulcers with or without neuropathic affectation in two departmental
hospitals of our institution. The medical records of these patients were
retrospectively reviewed. The selection and follow-up of patients was
uniformly carried out by a multidisciplinary “diabetic foot” team and
approved by the local ethics committee. All patients presented with
ischemic symptoms, revealed by clinical, duplex and transcutaneous
oximetry (TcPO2) assessment. In all cases, revascularization for critical
ischemia [2,3] and limb salvage was recommended [2,3,9] and clinical
outcome was assessed. The 152 limbs were treated by subintimal
(SA) and/or endoluminal (EA) primary angioplasty performed on
selected diabetic CLI neuroischemic foot wounds. If the endovascular
attempt failed, second-line surgical options were used. Twelve patients
underwent staged bilateral revascularization surgery. |
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| Eighty-six patients were men. A total of 132 ischemic limbs (87%)
were associated with type 2 diabetes and 20 ischemic limbs (20%) were
associated with type 1 diabetes. The mean age was 73.7 years (range 46-
95). Ninety-six patients (62%) were under an insulin-based treatment
regimen at the time of the surgery and 124 interventions (82%) were
performed on patients who had diabetes for more than five years.
Other patient characteristics and risk factors are summarized in Table
1. Foot ulcers, distal necrosis, swelling and local sepsis were present in different proportions in each case (Rutherford’s grade III, category 5
or Fontaine’s stage IV lesions) [2,3,9]. According to the UK screening
test [10], there were 43 limbs (28%) without perceivable neuropathic
affectation (NN subgroup), 70 limbs (46%) (1p - 7p) with moderate
neuropathic impairment (MN subgroup) and 39 limbs (26%) (8p -10p)
with severe neuropathy (SN subgroup) (Table 2). The subgroups were
matched for age, gender and type and duration of diabetes. Overall,
there were 57 Wagner’s grade 1-2 (37%) and 95 Wagner’s grade 3-4
(63%) ischemic foot lesions [11] (Table 1). Patients with extended
Wagner’s grade 5 [11] lesions, or equivalent Rutherford’s grade III
category 6 major tissue loss [2,3,9], facing inevitable major amputation
[1-3,11] were excluded from the study. Moreover, patients showing
common femoral artery lesions, infrainguinal aneurysmal disease,
recent occlusions with echolucent material (by systematic preoperative
duplex evaluation) or acute lower limb ischemic symptoms were
also not considered for this therapeutic approach. The endovascular
procedures performed on the main arterial trunks of the leg consisted
of 91 (60%) SA coupled to EA angioplasties, 29 (19%) SA angioplasties
and 32 (21%) multilevel EA angioplasties (Table 2). Fifty-one of the
152 cases (33%) were insulin-dependent diabetic patients and most of
them had multilevel arterial disease. The TASC type of lesions [2,3],
the extent of infragenicular atherosclerotic disease and the spread
of calcification are reported in Table 1. More than two thirds of
the patients had diabetes longer than 10 years, while 109 out of 152
(72%) limbs presented different stages of peripheral neuropathy [10]
associated with CLI features [2,3,9]. Other risk factors, comorbidities
and local features of the treated limbs are summarized in Table 1
according to the NN, MN and SN subgroups of patients. |
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| Methods |
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| Considering a homogeneous distribution of clinical features in all
subgroups (Table 1), the original protocol was designed to compare
postoperative outcome in terms of patency rates, clinical success
(ulcer healing) and limb salvage in the NN vs. MN and SN cohorts,
after a similar primary treatment by angioplasty. The results were
retrospectively recorded at equal time intervals. All patients had a similar
follow-up schedule, with comparable multidisciplinary “diabetic foot” management and regular per- and postoperative assessment (between
2005 and 2010). The preoperative variables recorded in all cases
were: initial clinical evaluation of the ischemic limb [2,3,9], clinical
features of diabetes [10,11] ankle-brachial index (ABI) or toe pressure
measurements (when technically feasible), Duplex scanning, TcPO2
and CT angiography or magnetic resonance imaging with detailed
views of the main crural and pedal arteries. Postoperative assessment
included specific follow-up variables, detailed in a further paragraph. |
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| Angioplasty technique |
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| Patients with preoperative impairment of renal function
were regularly hydrated and received N-acetylcysteine before the
intervention. All interventions were preceded by routine preoperative
antiplatelet therapy with daily administration of 160 mg of aspirin or
75 mg of clopidogrel, started at least 72 hours before the procedure.
The SA and EA angioplasty procedures were performed according
to previously published protocols [12-15] (Figure 1 and Figure 2).Access was typically achieved by ipsilateral antegrade femoral artery
puncture, but also through the contralateral femoral artery in some
cases. Retrograde access by popliteal or pedal puncture was not used
in this study. The lesions were crossed endo- or extraluminally with
hydrophilic 0.014-, 0.018- or 0.035-inch guidewires (Cook, UK or
Cordis, USA). Small amounts of contrast agent were progressively
injected to confirm the distal endoluminal localization. For the BTK
tibial and foot arteries, a 2-3 mm low-profile balloon in a monorail
0.014-inch system (Savy, Cordis, USA) or a stiffer 0.018-inch “overthe-
wire” system (ReeKross, Clear Stream Technologies Ltd., Ireland)
assisted by a 50 or 70 cm 6F introducer sheath (Cook, UK or Cordis,
USA) were specifically used. In 10 cases (7%), a cutting balloon (Boston
Inc., USA) was used because of dense calcifications in the calf or ankle
vessels. Selective stenting was performed in 39 cases (26%) for iliac,
superficial femoral artery or popliteal (P1) lesions. Synchronous staged
angioplasty without stent placement in the supragenicular arteries
was necessary in 34 cases (22%). In 79 specific cases (52%) presenting
severe focal infragenicular arterial disease, below-the-knee EA and SA
angioplasties confined to the distal popliteal (P2+P3) and tibial, pedal
or plantar trunks were performed (Access was typically achieved by ipsilateral antegrade femoral artery
puncture, but also through the contralateral femoral artery in some
cases. Retrograde access by popliteal or pedal puncture was not used
in this study. The lesions were crossed endo- or extraluminally with
hydrophilic 0.014-, 0.018- or 0.035-inch guidewires (Cook, UK or
Cordis, USA). Small amounts of contrast agent were progressively
injected to confirm the distal endoluminal localization. For the BTK
tibial and foot arteries, a 2-3 mm low-profile balloon in a monorail
0.014-inch system (Savy, Cordis, USA) or a stiffer 0.018-inch “overthe-
wire” system (ReeKross, Clear Stream Technologies Ltd., Ireland)
assisted by a 50 or 70 cm 6F introducer sheath (Cook, UK or Cordis,
USA) were specifically used. In 10 cases (7%), a cutting balloon (Boston
Inc., USA) was used because of dense calcifications in the calf or ankle
vessels. Selective stenting was performed in 39 cases (26%) for iliac,
superficial femoral artery or popliteal (P1) lesions. Synchronous staged
angioplasty without stent placement in the supragenicular arteries
was necessary in 34 cases (22%). In 79 specific cases (52%) presenting
severe focal infragenicular arterial disease, below-the-knee EA and SA
angioplasties confined to the distal popliteal (P2+P3) and tibial, pedal
or plantar trunks were performed (Table 2). At the completion of each
procedure, the vascular sheaths were removed and hemostasis was
attempted by manual compression. Closure devices were rarely used.
All patients were prescribed aspirin (160 mg/day) and clopidogrel (75
mg/day except in case of contraindication) for the first three months
after the procedure, followed by aspirin (160 mg/day) indefinitely.). At the completion of each
procedure, the vascular sheaths were removed and hemostasis was
attempted by manual compression. Closure devices were rarely used.
All patients were prescribed aspirin (160 mg/day) and clopidogrel (75
mg/day except in case of contraindication) for the first three months
after the procedure, followed by aspirin (160 mg/day) indefinitely. |
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Figure 1: Primary angioplasty approach in a diabetic critically ischemic, but
non-neuropathic left foot and ankle ulcer: a) The initial severe calf arteries
lesions: the Anterior and Posterior tibial arteries are occluded. The Peroneal
artery is the only supplying vessel to the foot; it shows severe, sub-occlusive
and multi-level atherosclerotic stenosis pointed by the two arrows. b) The arteriographic
result after staged angioplasties in the Peroneal artery, allowing a
correct flow to the lower ankle (upper arrow). Via its anterior communicants, the
Peroneal indirectly fills the left Dorsalis Pedis artery and further the foot arches
by retrograde flow (lower arrow). c) Initial clinical presentation of the left foot
ulcer. d) The clinical result at five months, with correct healing, by sharing a
multidisciplinary team approach that covers both, the ischemic and the neuropathic
aspect of the wound. |
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Figure 2:Staged angioplasties in the Posterior Tibial and the Plantar arteries
concerning a severe neuro-ischemic “Charcot” diabetic foot: a) The initial
Angio-CT presentation showing occlusions at different levels of all three tibial
arteries. b), c) Regaining the flow in Posterior Tibial and the Peroneal arteries.
d), e) Pursuing the angioplasties at the origin of the plantar arteries. f) The
prime clinical aspect of the right critically neuro-ischemic foot. g) The clinical
evolution at two months showing retarded healing in severe neuropathic background,
despite correct reopening of the Posterior Tibial and Peroneal flow. h)
Final result and correct cicatrization only after one year, owing persistent efforts
of the multidisciplinary “diabetic foot team”. |
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| Wound healing approach |
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| A standardized wound healing approach in accordance with the original study protocol was used in all three subgroups of patients,
regardless of their enrolment period. The protocol included urgent
debridement, expeditious revascularization, adapted wound dressings
and eventual negative-pressure wound therapy, depending on the
specific clinical indication. Off-loading devices were applied to patients
depending on the location of tissue defects, to favor ulcer healing on
the plantar, heel and side boundaries of the foot. |
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| Follow-up |
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| The patients were uniformly supervised by periodical clinical and
duplex scanning evaluation and regular ABI, neuropathic and TcPO2
assessment. Follow-up was scheduled one month after discharge and
every six months thereafter, with a mean duration of 32.3 months
(range 1-52). |
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| Definitions |
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| Lower-limb ischemia was clinically graded according to the revised
SVS/ISCVS criteria [9] and the TASC recommendations [2,3]. The
other “diabetic foot” clinical findings were ranked with the revised
Wagner’s classification [11] and the UK peripheral neuropathy
screening score (0-2: normal, 3-4: mild, 5-6: moderate and 7-9: severe
neuropathy) [10]. Sensory neuropathy was routinely quantified with
the Semmes-Weinstein monofilament [10]. Technical success was
defined as revascularization, allowing direct arterial flow from the
aorta to the pedal arches, with maximal residual arterial stenosis
under 25%. Patency was documented by periodic duplex scanning
and in all cases by ABI and TcPO2 measurements. Clinical success
was defined as a postoperative ABI increase > 0.10, with marked
improvements in wound healing (at least two Rutherford categories)
[2,3,9], with or without minor amputations (forefoot or toes). Limb
salvage was considered successful if there was no major amputation
and if the functional autonomy of the patient was recovered (walking
or standing). |
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| Statistical analysis |
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| All results were included in an “intention to treat” analysis. The
Kaplan-Meier life-table method was used to determine the outcome of primary and secondary patency, clinical success and limb salvage rates
[9]. These parameters were then compared among the NN, MN and
SN subgroups using log-rank (Mantel-Cox) and Breslow-Wilcoxon
tests. Additionally, specific risk factors were analyzed at one year as
categorical variables with the two-sided Fischer’s exact test. A p-value
< 0.05 was considered statistically significant. All data were analyzed
with the Prism statistics software (Graph Pad, San Diego, CA, USA). |
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| Results |
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| Primary infragenicular angioplasty was successful in 120 of 152
cases (79%). Technical success was achieved in 35 of 43 cases (81%) in
the NN subgroup, 56 of 70 cases (80%) in the MN subgroup and 29 of
39 cases (74%) in the SN subgroup. |
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| Of the 32 initially unsuccessful interventions, 25 (78%) were
performed with the SA technique and were unsuccessful because of a
failure to re-enter the true lumen (n=15) or difficulties in initiating the
subintimal dissection plane (n=10). The main SA-related limitations
were found in the SN subgroup (41% of cases featured extended
calcifications (Table 1). The other cases of technical failures were
three cases of unsealed arterial perforations, one case of elastic recoil
with collapsed extraluminal channel and early thrombosis and three
cases of unsuccessful endoluminal angioplasties, due to the presence
of extended annular wall calcifications. For all these initially failed
procedures, five surgical revascularizations, 23 adjuvant endovascular
interventions and four inevitable major amputations were required,
the latter because of extended calf and foot arterial occlusions, with no
other possible direct or indirect revascularization strategy, in a context
of life-threatening sepsis. |
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| The overall perioperative complication rate was 11.8% (18/152).
In eight cases (5.2%), major complications were noted: two limbs with
initial acute ischemia requiring prompt surgical revascularization, one
early myocardial infarction, two patients with transient renal failure
(contrast media-enhanced) and temporary dialysis and three groin
hematomas requiring surgical hemostasis. In the other 10 cases (6.5%),
minor complications with limited clinical repercussion were reported:
five arterial perforations with flow restriction, three distal embolisms
resolved by endo-aspiration and two superficial groin hematomas with
spontaneous local resolution. |
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| The 30-day survival rate was 99% (one case of myocardial
infarction). |
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| The cumulative primary and secondary patency rates (+/-SEM)
(Figure 3 and 4) were: 57% (+/-7%) and 72% (+/-7%) for NN, 50%
(+/-5%) and 66% (+/-6%) for MN with 38% (+/-8%) and 62% (+/-8%)
for SN subgroups at 12months; 46% (+/-8%) and 62% (+/-8%) for NN,
35% (+/-6%) and 54% (+/-7%) for MN and 27% (+/-7%) and 50% (+/-
9%) for SN cohorts at 24 months, correlated to 39% (+/-9%) and 62%
(+/-9%) for NN, 32% (+/-6%) and 49% (+/-7%) for MN and 26% (+/-
7%) and 45% (+/-9%) for SN contingents at 36 months, respectively.
The aggregate limb salvage and primary clinical success (Figures 5
and 6) showed: 90% (+/-5%) and 88% (+/-5%) for NN, 83% (+/-5%)
and 77% (+/-6%) for MN and 72% (+/-9%) and 68% (+/-9%) for SN
subgroups at 12 months; 85% (+/-7%) and 82% (+/-7%) for NN, 71%
(+/-7%) and 68% (+/-7%) for MN, 64% (+/-9%) and 57% (+/-9%) for
SN contingents at 24 months, added to 85% (+/-7%) and 69% (+/-10%)
for NN, 66% (+/-8%) and 62% (+/-8%) for MN and 59% (+/-10%) and
46% (+/-10%) for SN populations, at 36 months, respectively. |
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Figure 3: Primary Patency rates |
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Figure 4:Secondary Patency rates |
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Figure 5: Limb Salvage rates. |
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Figure 6: Clinical Success rates. |
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| Following the initial study protocol, the Log-rank (Mantel-Cox) test evaluation showed no statistical correlation between subgroups
(with or without neuropathy), neither for primary (p=0.172, CI: 0.924-
2.084, HR: 0.70, Chi square=1.85 for NN/MN and p= 0.152, CI: 1.310-
2.390, HR: 0.62, Chi square=2.05 for NN/SN), nor for the secondary
patency rates (p=0.335, CI: 0.372-1.401, HR: 0.72, Chi square=1.08 for
NN/MN and p= 0.176, CI: 0.269-1.272, HR: 0.58, Chi square=1.83 for
NN/SN). Using the same approach, there was a significant difference
between NN/SN subgroups for limb salvage (p=0.041, CI: 0.135-
0.960, HR: 0.36, Chi square=4.16), also for the primary clinical success
(p=0.048, CI: 0.185-0.996, HR: 0.42, Chi square=3.87). However, we
observed no statistical correlation when comparing the NN/MN tissue
recovery results (p=0.411, CI: 0.314-1.403, HR: 0.62, Chi square=1.72),
by the same method. |
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| Specific risk factors (Table 1) were also analyzed as categorical
variables at one year (average healing time three to 10 months), with the
two-sided Fischer’s exact test. End-stage renal disease was a negative
predictor in all subjects with or without peripheral neuropathy for
primary patency (p=0.0146 and p=0.0163), clinical success (p=0.0001 and p=0.0001) and limb preservation (p<0.0001 and p=0.0016) at
one year. Moreover, Wagner’s grade 3-4 and isolated infragenicular
atherosclerotic disease also appeared to be negatively associated with
limb salvage (p=0.170 and p<0.0001) and wound healing (p=0.050
and p<0.0001), but only in neuropathic patients (MN and SN) and at
similar time intervals. |
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| The mean increase in TcPO2 was 24.2 mmHg (range 16-37 mmHg)
in the NN subgroup, 21.4 mmHg (range 19-32 mmHg) in the MN
subgroup and 17.8 mmHg (range 14-28 mmHg) in the SN subgroup.
When comparing these data as categorical variables, a significant
difference between the postoperative TcPO2 values of the NN vs. MN
subgroups at one year (p=0.048, CI: 1.032-1.444, RR: 1.22) and the NN
vs. SN subgroups (p=0.012, CI: 1.068-1.733, RR: 1.36 and p=0.0068, CI:
1.094-1.946, RR: 1.45) was detected. |
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| A total of 107 wounds (70%) showed complete healing after
primary angioplasty. Thirty-two limbs (74%) in the NN subgroup and
75 (68%) in the MN+SN subgroups, including minor amputations,showed good recovery and regained ambulation. However, during
the first year of follow-up, unchanged or incomplete ulcer healing was
reported in 11 cases of 43 (26%) in the non-neuropathic and 34 cases
(32%) in the neuropathic (MN+SN) groups of patients. A total of 48
limbs (31%) developed iterative ulcerations mainly between the fourth
and tenth month after surgery. Nine cases (21%) were from the NN
subgroup and 39 (36%) from the MN+SN subgroups. Seventeen of
48 limbs presented wound relapses (35%), in whom the initial arterial
reconstruction was patent and only adjuvant local ulcer treatment was
administered, in addition to strengthened dietetic measures. |
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| Overall, there were 22 (14%) major amputations (four early
failures, six short-term disappointing wound evolutions and 12 others
throughout the entire follow-up period). The survival rates in this
cohort were 91%, 73%, 49% and 41% at 12, 24, 36 and 48 months,
respectively (Figure 7). |
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| Discussion |
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| Although surgery still plays a critical role in CLI revascularization
[2,17], parallel endovascular techniques emerge as comparable
alternatives in terms of limb salvage and clinical success. These
techniques are feasible in most cases and provide low invasiveness
and lower complication rates [5-7,17]. More specifically, for diabetic
patients, primary angioplasty has become increasingly suggested as
beneficial, providing low aggressiveness and applicability in challenging
crural [8,14,15,18] and below-the-ankle atherosclerotic locations [19]. |
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| The literature shows that although most diabetic lower-limb ulcers
appear neuropathic, there is ischemic involvement in more than 60% of
cases [4,11,20]. The recently published “OPIDIA Study” [21] suggests
that up to 87% of diabetic-infected foot wounds have a neuropathic
background (among 291 patients) and 62% also have chronic ischemic
presentation [21]. |
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| Among the multiple facets of “diabetic foot syndrome,” peripheral
neuropathic affectation currently encompasses distal symmetric
sensorimotor neuropathy and synchronous autonomic peripheral
denervation [20-22]. The former has been considered as the main
initiating factor for foot ulceration [1-4,11,20-22]. It seems to affect
approximately 30% of all diabetic people at any time and more than
50% of those having diabetes for more than 10 years [22]. Unlike
sensorimotor components, autonomic peripheral neuropathy requires
a more subtle clinical detection and stratification [4,21,22]. Neuropathy
and chronic ischemia are increasingly described as entangled entities within the complex etiology of diabetic foot wounds [21-23]. They
seem to present similar etiologic interactions within the wider group
of functional diabetic microangiopathies [21-23]. The synchronous
clinical presentation varying from subtle forms to more dominant
pathologies [22-23] are defining the so-called “neuroischemic diabetic
foot syndrome” [4,20]. |
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| The present study examined the potential efficacy of primary
endovascular treatment for neuroischemic limbs. According to the
initial protocol, despite non-significant (p=0.172) primary assisted
and secondary patency rates revealed in the NN (57% and 72% at 12
months) vs. MN (50% and 66% at 12 months) or SN subgroups (38%
and 62% at 12 months), we observed a significant correlation between
limb salvage and clinical success (p=0.048 and p=0.041) in the NN (90%
and 88% at 12 months, 85% and 69% at 36 months) vs. the MN (83%
and 77% at 12 months, 66% and 62% at 36 months) and SN subgroups
(72% and 68% at 12 months, 59% and 46% at 36 months). These data
suggest a probable better tissue recovery in non-neuropathic diabetic
CLI patients after successful hypoxic relief, even though the surveillance
from the diabetic team was similar in all patients. |
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| We also detected a significant difference between postoperative
TcPO2 values in NN vs. MN (p=0.048, CI: 1.032-1.444, RR: 1.22) and
NN vs. SN patients (p=0.012, CI: 1.068-1.733, RR: 1.36) at one year.
These results might reflect a better cutaneous irrigation after large tibial
trunk angioplasty in the NN vs. MN and SN cohorts. However, this
hypothesis should be considered with caution because of the dissimilar
neuropathic affectation of capillary microcirculation [15,16,23] and
“patchy” O2 redistribution to the skin [15,16,23]. |
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| Several variables were analyzed as risk factors for patency, ulcer
healing and limb salvage. End-stage renal disease was negatively
associated in all subgroups with or without distal sensorimotor
neuropathy with primary patency (p=0.0146 and p=0.0163), clinical
success (p=0.0001 and p=0.0001) and limb preservation (p < 0.0001
and p=0.0016) at one year. The extent of tissue defects (Wagner’s grade
3-4) was negatively associated with limb salvage (p=0.170) and wound
recovery (p=0.050), but only in the neuropathic MN and SN subgroups.
These results are in accordance with previous observations in the same
field of research [4,11,15,18,20,23]. |
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| We also analyzed eventual concurrent risk factors that could affect
technical success (81% in the NN, 80% in the MN and 74% in the SN
subgroups) and primary patency after the initial angioplasty approach
(Figure 3). Although the results were not statistically significant
considering cumulative patency (p>0.05), we detected an increase
in technical failures and precocious postoperative thrombosis in the
SN subgroup (NN=19%, MN=20% and SN=26%). This was mainly
attributed to the extensive (>3 cm) and bulky arterial wall calcifications
(NN=35%, MN= 37% and SN=41%) (Table 1), requiring more
fastidious endovascular manipulations. |
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| Following the same initial protocol, a significant difference in
tissue healing and limb salvage was detected at one year between purely
ischemic (NN) and neuroischemic (MN+SN) limb wounds (p<0.0001,
CI: 0.321-0.704, RR: 0.47 and p<0.0001, CI: 1.942-1.304, RR: 0.49). As
mentioned before, these cases were also frequently associated with
extended and highly calcified TASC D lesions [3] (NN=48%, MN=47%
and SN=59%) (Table 1). Although not assessing specific etiologic
associations, some authors proposed a possible association between the
severity of neuropathy and the extent of tibial calcifications in “diabetic
foot syndrome” [20,22]. |
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| Limitations |
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| Two limitations of this study are the small number of cases and
its retrospective aspect. Moreover, the technical performance of the
vascular interventionists and other professionals of the diabetic team
have undoubtedly changed over the observation period, together with
technical and technological advances in the field. Further data from
prospective and larger multicenter studies are necessary to confirm
these results and draw pertinent conclusions on the effects of diabetic
neuropathy on limb salvage and revascularization. |
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| Conclusion |
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| Cumulative patency following first-line angioplasty in diabetic
ischemic limbs seems unsubstantially affected by concomitant
peripheral neuropathy. However, despite appropriate revascularization,
severe diabetic neuropathy may impede correct postoperative wound
healing and related limb salvage rates. |
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| References |
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