Keywords
free tissue transfer - free flap reconstruction - microsurgery - sickle cell disease
Introduction
Sickle cell disease (SCD) is an inherited hemoglobinopathy affecting around 1 in 500
African Americans, with an additional 1 in 12 being carriers of the autosomal recessive
mutation.[1] Internationally, the prevalence of SCD is high among the sub-Saharan African, South
Asian, Middle Eastern, and Mediterranean populations. With increasing human migration,
the number of people affected by SCD is predicted to increase exponentially particularly
in countries not historically endemic for SCD.[2]
SCD was first described by James Herrick in 1910, who published a case report of severe
anemia in a 20-year-old African male from Grenada with a “large number of thin, elongated,
sickle-shaped, and crescent-shaped” erythrocytes.[3] Though Herrick did not understand the pathophysiology at that time, he astutely
noted that “some unrecognized change in the composition of the corpuscle itself may
be the determining factor.” In 1949, Pauling et al demonstrated that SCD was a “molecular
disease” with a genetic basis for the abnormal hemoglobin S (HbS) protein.[4] HbS has single amino acid change from glutamine to valine in the β-globin chain
of hemoglobin, causing polymerization in relative hypoxemia. SCD may be caused by
the homozygous genotype HbSS, or it may be caused by compound heterozygous genotypes
of HbS and other β-globin variants affecting structure or quantity, such as HbC and
Hb β-thalassemia, respectively. Polymerization of HbS leads to changes in the structure
and function of erythrocytes, including deformation into a sickle shape, increased
stiffness, and increased adhesion. Repeated erythrocyte sickling shortens their lifespan,
leading to chronic hemolytic anemia, microvascular thrombosis affecting all organs,
and vaso-occlusive events. Furthermore, these events trigger a complex cascade leading
to a proinflammatory and hypercoagulable state.[1] Known triggers of sickling include hypoxia, infection, dehydration, cold, circulatory
stasis, and stress.
Traditionally, SCD is a relative contraindication for free tissue transfer, as obligate
transient flap ischemia and tissue hypoxia may trigger sickling and microvascular
thrombosis. Moreover, SCD patients are hypercoagulable and have increased risks of
a wide range of perioperative and postoperative complications, including acute chest
syndrome, cerebrovascular stroke, vaso-occlusive crisis, acute kidney injury, venous
thromboembolism, and pulmonary embolism (PE).[5]
The purpose of this article is twofold. First, the authors describe a case report
with the successful use of free tissue transfer in a patient with SCD. Second, the
authors perform a systematic literature review to identify previous cases of free
tissue transfer in SCD, to determine published success and complication rates, and
to review reported preoperative, intraoperative, and postoperative management strategies.
A retrospective chart review was performed of a patient with SCD who underwent free
tissue transfer for soft tissue coverage of a large craniofacial defect. Medical history,
preoperative workup and interventions, operative details, postoperative management,
and complications were recorded. As a single case report, this study was exempted
by the Institutional Review Board at our institution. Written consent was obtained
for the use of patient photographs.
A systematic literature review using the Preferred Reporting Items for Systematic
Reviews and Meta-Analyses guidelines was performed using the keywords “free tissue
transfer,” “free flap,” or “microsurgery” and “sickle cell” on PubMed, Ovid/Medline,
and Scopus. Any relevant publications identified in the references of these articles
were also included for review. Two authors then independently evaluated these articles
and identified those describing cases of free tissue transfer in SCD. Articles that
described other types of flaps, described free tissue transfer in sickle cell trait
(SCT), were about other topics, or were not written in English were excluded. The
articles describing cases of free tissue transfer in SCD were queried for data on
patient demographics, preoperative laboratory values, preoperative workup and interventions,
indications for free tissue transfer, operative details, postoperative management,
and complications.
Case
A 29-year-old African American male presented to the emergency department with right
lower extremity swelling and a large, infected wound over the right face and scalp
([Fig. 1A]). Two months prior to presentation, he was pushed onto a subway live rail, suffering
an electrical burn to the right face and scalp. He was admitted to an outside hospital,
underwent excisional debridement and placement of Integra bilayer matrix wound dressing
(Integra LifeSciences, Princeton, NJ), then left against medical advice, and was lost
to follow-up. Past medical history was notable for SCD on hydroxyurea with prior episodes
of vaso-occlusive crises and acute chest syndrome, history of deep vein thrombosis
(DVT), cholecystitis status post-cholecystectomy, and chronic pain with opioid dependence.
His state was further complicated by a complex social history including drug abuse
and unstable housing.
Fig. 1 (A) Patient appearance on emergency department presentation. There is a large right
face and scalp eschar with overlying Integra silicone sheet still in place, and purulent
drainage from the right globe. (B) Patient appearance after excisional debridement of face and scalp wounds and right
orbital exenteration.
The patient was admitted to our institution's Burn and Complex Wound Center. Notable
admission laboratory findings included hemoglobin (Hgb) 7.8 g/dL and HbS 7.0%. Although
his HbS value was unusually low, most likely due to receiving blood transfusions during
recent admissions at outside hospitals, the patient's HbS 1 year prior was 55.3% which
is more consistent with SCD. Venous duplex imaging demonstrated a partially occlusive
DVT of the gastrocnemius vein corresponding to his right lower extremity swelling
and pain. Hematology was consulted and recommended packed red blood cell (pRBC) transfusion
with goal Hgb > 10 g/dL, exchange transfusion as needed to keep HbS < 30%, and 3 months
of anticoagulation for the DVT. The patient was transfused 2 units of pRBCs to bring
his Hgb to 10.0. As the HbS was 7.0%, no exchange transfusion was performed, and a
therapeutic heparin drip was initiated for anticoagulation.
One day after admission, the patient underwent excisional debridement of the face
and scalp wounds and right orbital exenteration, resulting in a large defect with
exposed craniomaxillofacial bones ([Fig. 1B]). Intraoperative quantitative tissue cultures grew multiple drug resistant organisms
including Escherichia coli, Bacillus, coagulase negative Staphylococcus, Corynebacterium amycolatum, and Candida which were treated with topical antimicrobials and intravenous broad-spectrum antibiotics
per Infectious Disease recommendations.
One week after debridement, the patient underwent definitive wound closure with a
left anterolateral thigh (ALT) free flap ([Fig. 2]). Repeat HbS prior to reconstruction was 6.6%. The flap pedicle was anastomosed
to the right superior thyroid artery and vein in end-to-end fashion. Technical issues
requiring multiple revisions of the arterial anastomosis led to a total ischemia time
of 133 minutes. Due to prolonged ischemia time, topical ice was used to cool the flap.
Total operative time was 12 hours. Patient temperature was maintained between 36.1
and 38.1°C. He was transfused with 4 units of pRBCs and 2 units of fresh frozen plasma
to maintain Hgb > 10 g/dL intraoperatively. The flap was monitored using a continuous
implantable Doppler on the flap artery (Cook-Swartz Doppler Probe, Cook Medical, Bloomington,
IN), continuous tissue oximetry monitoring (ViOptix, Newark, CA), cutaneous Doppler
signals, and hourly clinical flap checks.
Fig. 2 Immediate postoperative appearance after free anterolateral thigh (ALT) flap reconstruction.
On postoperative day 1, the patient developed progressive neck swelling at the site
of the anastomosis, flap swelling causing dehiscence at the left upper eyelid suture
line, and downtrending ViOptix readings ([Fig. 3A]). Operative exploration found old hematoma in the neck and under the flap but no
active bleeding. The flap was unable to be reclosed due to swelling, so it was re-inset
to allow for left upper eyelid closure, leaving a small part of the left upper scalp
open ([Fig. 3B]). The hematoma was attributed to postoperative hypertension and supratherapeutic
heparin drip (partial thromboplastin time > 100 seconds).
Fig. 3 (A) Right neck and flap swelling on postoperative day 1 causing dehiscence at the left
upper eyelid suture line. Progressive swelling and downtrending ViOptix readings were
concerning for hematoma causing impending flap compromise, and the patient was taken
to the operative room urgently for flap exploration. (B) Flap re-inset after hematoma evacuation, leaving an open area at the left scalp.
The remaining hospital course was unremarkable from a flap perspective. The patient
was transfused as needed to maintain Hgb > 10 g/dL. Postoperative HbS was < 5.0%.
Anticoagulation consisted of aspirin 81 mg daily for empiric free flap thromboprophylaxis
and apixaban 5 mg twice daily for 3 months for the right lower extremity DVT. There
were no SCD-related complications. At 1-month follow-up, the flap remained viable
and the left scalp wound was healing well with silver sulfadiazine dressing changes
([Fig. 4]).
Fig. 4 Patient appearance at 1 month postoperatively. The flap remains viable and the open
wound on the left scalp is nearly healed with dressing changes.
Systematic Review
As depicted in [Fig. 5], we identified 83 articles, 26 of which were unique and 57 of which were duplicates.
We believe the smaller number of unique articles and larger number of duplicates reflect
the paucity of reports on this topic. It also likely reflects that each database encompasses
a vast majority of the available literature, leading to considerable overlap. Two
additional papers were found outside of the literature search from references within
these 26 identified articles. Of the total of 28 articles, 7 articles described 13
cases of free tissue transfer in 10 patients with SCD.[6]
[7]
[8]
[9]
[10]
[11]
[12] Preoperative, intraoperative, and postoperative details of each case are summarized
in [Tables 1],[2],[3] respectively. Seven articles describing free tissue transfer in SCT were excluded
from analysis but reviewed in the “Discussion” section.[13]
[14]
[15]
[16]
[17]
[18]
[19]
Fig. 5 Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) diagram
detailing systematic literature review using the keywords “free tissue transfer,”
“free flap,” or “microsurgery” and “sickle cell” on PubMed, Ovid/Medline, and Scopus
in September 2021. Articles that described pedicled flaps, that described free tissue
transfer in sickle cell trait (SCT), were about other topics, or were not written
in English were excluded. Seven articles describing cases of free tissue transfer
in sickle cell disease (SCD) were identified.
Table 1
Preoperative details of 13 free flap cases in 10 patients with SCD reported in the
literature
|
Case number
|
Authors
|
Year
|
Age/gender
|
Hemoglobin genotype
|
Preoperative
exchange transfusion
|
Preoperative or listed goal HbS (%)
|
Preoperative or listed goal Hgb (g/dL)/Hct (%)
|
|
1
|
Chang et al.
|
2022
|
37 M
|
HSBT
|
Yes
|
65 to 14
|
Hb > 10 g/dL
|
|
2
|
Weinzweig et al.
|
1997
|
36 F
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
3
|
Weinzweig et al.
|
1997
|
36 F
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
4
|
Weinzweig et al.
|
1997
|
35 M
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
5
|
Weinzweig et al.
|
1997
|
35 M
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
6
|
Monga et al.
|
1996
|
37 M
|
HbSS
|
Yes
|
|
|
|
7
|
Weinzweig et al.
|
1995
|
25 F
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
8
|
Weinzweig et al.
|
1995
|
21 F
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
9
|
Weinzweig et al.
|
1995
|
38 F
|
HbSS
|
Yes
|
< 30
|
Hct 31–35
|
|
10
|
Richards et al.
|
1992
|
26 F
|
HbSS
|
Yes
|
74 to 23.6
|
12.6 g/dL
|
|
11
|
Khouri and Upton
|
1991
|
33 M
|
HbSS
|
Yes
|
Unknown to 24.0
|
|
|
12
|
Khouri and Upton
|
1991
|
33 M
|
HbSS
|
Yes
|
26.0
|
|
|
13
|
Spence
|
1985
|
19 M
|
HbSS
|
Yes
|
33.8
|
|
Abbreviations: HbSS, sickle cell disease; Hct, hematocrit ; HSBT, hemoglobin S β-thalassemia.
Table 2
Intraoperative details of 13 free flap cases in 10 patients with SCD reported in the
literature
|
Case number
|
Defect
|
Flap
|
STSG
|
Recipient vessels
|
Anastomosis technique
|
Ischemia time (min)
|
Operative time (h)
|
Additional operative details
|
|
1
|
Chronic osteomyelitis of the mandible
|
Adipofascial radial forearm
|
No
|
L facial artery and external jugular vein
|
|
16
|
|
No tourniquetNo cooling
|
|
2
|
R chronic leg wound
|
Hemi omentum
|
Yes
|
R posterior tibial artery and vein
|
Artery: end to side
|
90
|
12
|
Flap flushed with 200 mL of 5000 U heparin and dextran 40 solutionIV dextran 40 and
ASA given prior to anastomosis
|
|
3
|
L chronic leg wound
|
Hemi omentum
|
Yes
|
L posterior tibial artery and vein
|
|
60
|
12
|
Flap flushed with 200 mL of 5000 U heparin and dextran 40 solutionIV dextran 40 and
ASA given prior to anastomosis
|
|
4
|
R chronic leg wound
|
Hemi omentum
|
Yes
|
R anterior tibial artery and vein
|
|
90
|
11
|
Flap flushed with 200 mL of 5000 U heparin and dextran 40 solutionIV dextran 40 and
ASA given prior to anastomosis
|
|
5
|
L chronic leg wound
|
Hemi omentum
|
Yes
|
L anterior tibial artery and vein
|
|
150
|
11
|
Flap flushed with 200 mL of 5000 U heparin and dextran 40 solutionIV dextran 40 and
ASA given prior to anastomosis
|
|
6
|
Penile autoamputation
|
Radial forearm
|
No
|
|
|
|
|
Penile prosthetic device placed within neophallus
|
|
7
|
R chronic ankle wound
|
L latissimus dorsi
|
Yes
|
R posterior tibial artery and vein
|
Artery: end to sideVein: end to end with cephalic vein graft
|
50
|
7
|
Cephalic vein graft with two valves
|
|
8
|
L chronic ankle wound
|
R latissimus dorsi
|
Yes
|
L posterior tibial artery and vein
|
Artery: end to sideVein: end to end
|
90
|
7.5
|
None reported
|
|
9
|
L foot contact burn wound
|
R temporoparietal fascia
|
Yes
|
L dorsalis pedis artery and vein
|
Artery: end to endVein: end to end
|
|
|
None reported
|
|
10
|
L chronic ankle wound
|
L radial forearm
|
|
L posterior tibial artery and VC x 2
|
Artery: end to sideVein: end to end
|
|
|
None reported
|
|
11
|
L chronic leg wound
|
L latissimus dorsi
|
Yes
|
L dorsalis pedis artery and anterior tibial VC
|
Artery: end to endVein: end to end
|
16
|
|
None reported
|
|
12
|
R chronic leg wound
|
R latissimus dorsi
|
Yes
|
R posterior tibial artery and VC
|
Artery: end to sideVein: end to end
|
|
|
5000 U IV heparin bolus given at time of vascular clamping
|
|
13
|
L chronic ankle wound
|
Gracilis
|
Yes
|
L anterior tibial artery and vein
|
|
90
|
|
Flap cooling (20 minute of cold ischemia time)
|
Abbreviations: ASA, aspirin; IV, intravenous; SCD, sickle cell disease; STSG, split-thickness
skin graft; VC, venae comitantes.
Table 3
Postoperative details and complications of 13 free flap cases in 10 patients with
SCD reported in the literature
|
Case number
|
Postoperative Hgb goal
|
Postoperative anticoagulation
|
Flap compromise
|
Wound infection
|
STSG loss
|
Operative intervention
|
Flap survival
|
Wound coverage
|
Follow-up (mo)
|
|
1
|
> 8 g/dL
|
|
No
|
No
|
N/A
|
No
|
Yes
|
Yes
|
8
|
|
2
|
> 12 g/dL
|
IV dextran 40 × 5 dASA 325 mg × 2 wk
|
No
|
Yes (Pseudomonas)
|
|
Delayed skin grafting
|
Yes
|
Yes
|
24
|
|
3
|
> 12 g/dL
|
IV dextran 40 × 5 dASA 325 mg × 2 wk
|
No
|
Yes (Pseudomonas)
|
|
Delayed skin grafting
|
Yes
|
Yes
|
24
|
|
4
|
> 12 g/dL
|
IV dextran 40 × 5 dASA 325 mg × 2 wk
|
No
|
Yes (Pseudomonas)
|
|
Delayed skin grafting
|
Yes
|
Yes
|
|
|
5
|
> 12 g/dL
|
IV dextran 40 × 5 dASA 325 mg × 2 wk
|
No
|
Yes (Pseudomonas)
|
|
Delayed skin grafting
|
Yes
|
Yes
|
|
|
6
|
|
|
No
|
No
|
|
Delayed penile prosthesis revision
|
Yes
|
Yes
|
60
|
|
7
|
|
|
Yes (9 hours postop) - intraflap microvascular thrombosis
|
No
|
|
YesPOD0: flap explorationPOD4: flap debridement and re-insetPOD15: flap debridement
and STSG
|
No
|
Yes
|
36
|
|
8
|
|
|
No
|
Yes (Pseudomonas)
|
|
YesPOD7: flap debridementPOD14: delayed skin grafting
|
Partial
|
Yes
|
17
|
|
9
|
|
|
No
|
No
|
Yes
|
|
Yes
|
Yes
|
55
|
|
10
|
Hgb > 12 g/dLHbS < 16%
|
None until complications, then IV heparin
|
Yes (3 d postop) - artery
|
No
|
|
YesPOD3: flap explorationPOD ?: flap debridement, skin grafting
|
No
|
Yes
|
|
|
11
|
|
None until complications, then IV heparin and ASA x 10 days
|
Yes (2 d postop) - artery
|
No
|
Yes
|
YesPOD2: flap explorationPOD ?: delayed skin grafting
|
Yes
|
Yes
|
24
|
|
12
|
|
ASA x 2 wk
|
No
|
No
|
Yes
|
Delayed skin grafting
|
Yes
|
Yes
|
24
|
|
13
|
|
|
No
|
No
|
No
|
No
|
Yes
|
Yes
|
24
|
Abbreviations: ASA, aspirin; IV, intravenous; POD, postoperative day; SCD, sickle
cell disease; STSG, split-thickness skin graft;.
Note: Flap survival - Flap survival was defined as “Yes” if there was complete flap
survival, “Partial” if > 50% of the flap survived, and “No” if < 50% of the flap survived.
Patient ages ranged from 19 to 38 years old (average 30.7 years), with five males
and five females. All cases had preoperative exchange transfusions. Goal HbS was < 30%,
except for one case where it was 33.8% and one where it was not reported. All cases
had a Hgb transfusion goal of > 10 g/dL, except for four cases where it was not reported
([Table 1]).
Free tissue transfer was indicated for lower extremity wounds (n = 11), chronic mandibular osteomyelitis (n = 1), and penile autoamputation secondary to recurrent ischemic priapism (n = 1). Free flaps included latissimus dorsi (n = 4), hemi omentum (n = 4), radial forearm (n = 3), temporoparietal fascia (n = 1), and gracilis (n = 1). Ischemia time ranged from 16 to 150 minutes (average 72 minutes) and was not
reported for four cases. Total operative time ranged from 7 to 12 hours (average 10.1 hours)
and was not reported for seven cases. Four flaps were flushed with a 200-mL solution
consisting of 5,000 units of heparin and dextran 40 solution prior to anastomosis.
Five cases reported systemic anticoagulation prior to anastomosis, four cases gave
intravenous dextran 40 and enteral aspirin, and one case gave a bolus of intravenous
heparin 5,000 units ([Table 2]).
The most common postoperative complications were flap compromise in three flaps and
superficial wound infection in five flaps. These cases of superficial wound infection
resulted in partial skin graft loss requiring repeat skin grafting in delayed fashion.
However, no cases of superficial wound infection led to flap loss. Flap compromise
was caused by arterial thrombosis in two cases and intraflap microvascular thrombosis
in one case. Postoperative anticoagulation trends were variable. Four cases used intravenous
dextran 40 for 5 days and aspirin 325 mg daily for 2 weeks. One case reported the
use of aspirin for 2 weeks but did not specify the dose. Two cases did not use anticoagulation
until signs of flap compromise. Ten out of 13 flaps required further operative intervention
with flap exploration (n = 3), flap debridement (n = 3), repeat skin grafting (n = 9), and penile prosthesis revision (n = 1). Ten cases reported complete flap survival, one reported survival of more than
two-thirds of the flap, and two reported loss of more than half of the flap. However,
all defects were successfully closed with follow-up of 8 to 60 months ([Table 3]).
Flap compromise occurred in cases 7, 10, and 11. In case 7, flap compromise was noted
9 hours postoperatively with decreased cutaneous Doppler signal and poor flap bleeding
after a transient hypothermic and hypotensive episode.[9] Operative exploration showed patent pedicle vessels, and flap compromise was attributed
to microvascular thrombi in the flap circulation. The flap was managed expectantly
with two further debridements removing 75% of the flap thickness, but the wound was
successfully closed with skin grafting. No information on postoperative Hgb, HbS,
or anticoagulation was reported.
Flap compromise in case 10 was noted on postoperative day 3 with a pale flap appearance.[10] Operative exploration showed extensive thrombus in the posterior tibial artery,
starting in the proximal lower leg and extending into the flap. Flap salvage was attempted
with Fogarty catheter thrombectomies, a bolus of intravenous heparin 5,000 units,
revision of the arterial anastomosis from end-to-side to end-to-end, and flap infusion
of 35,000 units of streptokinase for 1 hour. Ischemia time was 6 hours and most of
the flap demarcated. Interestingly, histology of the debrided flap showed thrombus
without sickled cells, and HbS at the time of flap compromise was 16.6%. The wound
was successfully closed with skin grafting.
Flap compromise in case 11 was noted on postoperative day 2 with decreased flap temperature.[11] Operative exploration showed thrombus at the arterial anastomosis extending into
the flap. Flap salvage was successful with flap infusion of streptokinase and anastomosis
revision from end-to-end to the dorsalis pedis artery to end-to-side to the anterior
tibial artery. Ischemia time was 4 hours. Systemic anticoagulation was also instituted
with intravenous heparin and aspirin for 10 days. Postoperative HbS was not reported.
Discussion
SCD has traditionally been considered a contraindication for free tissue transfer
due to concerns of higher risks of flap failure from sickling and generalized hypercoagulability.
This article reports a successful case of a free ALT flap in a patient with SCD and
presents a systematic literature review identifying 13 cases of free tissue transfer
in 10 patients with SCD.
All 13 cases used exchange transfusions and/or pRBC transfusions preoperatively, with
most cases reporting goals of lowering HbS to < 30% and raising Hgb to > 10 g/dL.
The concept of using preoperative blood transfusions in SCD to elevate hemoglobin,
reduce reticulocyte count, and suppress sickle cell production was first described
in 1969 for patients undergoing skin grafting for sickle cell ulcers.[20] The idea of using preoperative exchange transfusions emerged later, as it was found
that the filterability of blood in SCD patients is normal when HbS is < 40% and that
vaso-occlusive crises occur only when HbS is > 50%.[21]
[22] A 2020 Cochrane meta-analysis found insufficient evidence to recommend aggressive
preoperative blood transfusions in SCD to prevent sickle-related or surgery-related
complications,[23] but it should be strongly considered in free tissue transfer where the risk of sickling
and thrombosis should be minimized.
While the main focus of preoperative optimization is on the hematologic system, it
is worth mentioning that SCD affects all organ systems, especially the respiratory,
gastrointestinal, neurologic, and immunologic systems.[5] Our patient was relatively young but had many of the chronic manifestations of SCD,
like all cases in the literature review with an average age of 30.7 years. This is
likely due to selection bias, as older SCD patients may be considered poor free flap
candidates in an already high-risk population. In addition, the projected life expectancy
for people with SCD versus general population in the United States is 54 versus 76
years.[24]
Our review did not identify any operative considerations to minimize the risk of flap
loss. Because sickling is induced by local tissue hypoxia, cold temperatures, and
circulatory stasis, it is reasonable to assume that flap ischemia time, flap cooling,
and tourniquet use should be minimized. However, the three cases that suffered thrombotic
events had reported 50 and 16 minutes of ischemia time (not reported for case 10).
Our flap ischemia time was 133 minutes, and we cooled the flap due to longer ischemia
time. The decision to use topical ice to cool the flap was made in this case because
the authors believed that the risks of prolonged warm ischemia time causing irreversible
tissue death outweighed the risks of cold temperature causing sickling. Upon review
of the available cases, case 13 was also cooled for 20 minutes and completely survived
as well.[12] McAnneny et al reported a case of bilateral immediate transverse rectus abdominis
muscle flaps in a patient with SCT who suffered unilateral flap thrombosis and failure
on the side that was cooled in an ice bath for 25 minutes.[14] Pathology showed sickled cells in the flap microvasculature. Because the two flaps
were otherwise treated the same, the authors concluded that flap cooling was the principal
cause of intraflap microvascular thrombosis. In our review, a tourniquet was not used
in one radial forearm free flap and was not reported in the two other radial forearm
free flap cases, making it difficult to draw conclusions about whether tourniquet
use during flap elevation affects flap survival.[6]
[8]
[10] Two literature reviews report that tourniquets can be used safely in patients with
SCD and SCT, but with a complication rate of 12.5% including extremity swelling, severe
pain, infection, or DVT/PE.[25]
[26]
The reported use of intraoperative intraflap and/or systemic anticoagulation was mixed.
In their 1997 case series, Weinzweig et al flushed their flaps with 200 mL of dextran
40 and 5,000 units of heparin and administered systemic anticoagulation with intravenous
dextran 40 and aspirin prior to anastomosis,[7] but the same group did not report using this protocol in their 1995 case series.[9] Neither article reports why these changes were made. Intraflap and systemic anticoagulation
were used to help rescue cases 10 and 11 during operative takeback for flap arterial
compromise.
Our review also did not identify any recommendations on postoperative management.
Again, it is reasonable to assume that triggers of sickling should be avoided, and
thus patient normothermia, oxygenation, hydration, and analgesia should be maintained.
In addition, close monitoring of pulmonary, gastrointestinal, renal, or thromboembolic
dysfunction is required as SCD patients are at an estimated sickle-related postoperative
complication rate of 17% with mortality figures of 1%.[5]
There were three reported cases of flap compromise caused by arterial thrombosis in
two cases and intraflap microvascular thrombosis in one case,[9]
[10]
[11] despite preoperative optimization to lower HbS and raise Hgb ([Table 3]). Of note, the timing of arterial thrombosis was relatively delayed in cases 10
and 11. Although preoperative exchange transfusions and pRBC transfusions dilute abnormal
erythrocytes, SCD patients still have generalized hypercoagulability. This suggests
that postoperative anticoagulation should be considered.
Postoperative anticoagulation protocols from our review were varied ([Table 3]). In our case report, we initiated a therapeutic intravenous heparin drip preoperatively
for DVT treatment and added aspirin 81 mg daily postoperatively for flap thromboprophylaxis.
However, the use of both intravenous heparin and aspirin likely contributed to our
patient's hematoma, causing acute flap compromise. Similarly, Young-Afat et al report
a patient with SCT who was treated with therapeutic low molecular weight heparin after
a unilateral deep inferior epigastric perforator flap complicated by hematomas at
both the flap and donor site requiring operative takeback.[16] These examples highlight the fine balance between managing complications from bleeding
versus clotting in this unique patient population.
The second most common postoperative complication in our systematic review was superficial
wound infection in five patients causing skin graft loss. Interestingly, all reported
infections were caused by Pseudomonas ([Table 3]). Studies on the microbial flora of sickle cell chronic leg wounds have shown that
Pseudomonas aeruginosa is the second most common bacteria isolated after Staphylococcus aureus.[27]
[28] This likely reflects differences in microbial flora in SCD patients due to their
functional asplenia and relative immunocompromise, making them at higher risk for
infection with encapsulated bacteria.[29]
Although only 10 out of 13 flaps completely survived, all defects were successfully
reconstructed. Even in cases of > 50% flap loss, enough of the flap survived to allow
for skin grafting over a vascularized wound bed. The concept that “free tissue failure
is not an all-or-none phenomenon” is an important one,[30] particularly in a patient population that is traditionally considered not to be
good candidates for free tissue transfer.
This article describes a case report and systematic literature review on 13 cases
of successful free tissue transfer in SCD. Due to the paucity of cases, it is difficult
to draw specific conclusions on how to best approach free tissue transfer in SCD.
All cases recommended preoperative optimization by reducing HbS to < 30% and keeping
Hgb > 10 g/dL to minimize sickling and reticulocyte production of abnormal cells.
There were no generalizable trends regarding intraoperative or postoperative optimization.
It is important to be mindful that the pathologic effects of chronic hemolysis, microvascular
thrombosis, and vaso-occlusive events can lead to progressive end-organ damage as
well as a proinflammatory and hypercoagulable state, and that these effects are systemic
and require multidisciplinary care. For complex defects in SCD patients, reconstruction
with free tissue transfer can be successful with medical and surgical optimization.
