- Email: [email protected]
Multidisciplinary Approach to Treatment of Soft Tissue Sarcomas Requiring Complex Oncologic Resections
Accepted Manuscript Multidisciplinary Approach to Treatment of Soft Tissue Sarcomas Requiring Complex Oncologic Resections Nadia Awad, Richard Lackman, Katherine McMackin, Tae Won Kim, Joseph Lombardi, Francis Caputo PII:
S0890-5096(18)30485-0
DOI:
10.1016/j.avsg.2018.04.035
Reference:
AVSG 3920
To appear in:
Annals of Vascular Surgery
Received Date: 4 June 2017 Revised Date:
14 April 2018
Accepted Date: 19 April 2018
Please cite this article as: Awad N, Lackman R, McMackin K, Kim TW, Lombardi J, Caputo F, Multidisciplinary Approach to Treatment of Soft Tissue Sarcomas Requiring Complex Oncologic Resections, Annals of Vascular Surgery (2018), doi: 10.1016/j.avsg.2018.04.035. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1 1
Title Page Multidisciplinary Approach to Treatment of Soft Tissue Sarcomas Requiring Complex
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Oncologic Resections
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Nadia Awad1, Richard Lackman2, Katherine McMackin1, Tae Won Kim2,
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Joseph Lombardi1, Francis Caputo1
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Division of Vascular Surgery, Department of Surgery
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Cooper Medical School of Rowan University, Camden, NJ 2
Department of Orthopedic Surgery
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Cooper Medical School of Rowan University, Camden, NJ
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Nadia Awad
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5401 Old York Road
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Suite 203
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Philadelphia, PA 19141
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E-mail: [email protected]
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Phone: (215) 456-6178
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Fax: (215) 456-6204
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Abstract
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Objective: To review the experience and outcome of utilizing a multidisciplinary team, including
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vascular surgery and orthopedic surgery, in the operative treatment of soft tissue sarcomas (STS)
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at an academic, tertiary care hospital.
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27 Methods:
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A retrospective review was performed of all patients who underwent elective STS
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resection between July 1, 2012 and January 31, 2015, since the addition of a specialized cancer
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treatment center and a dedicated oncologic division of orthopedic surgery. Surgical cases
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performed in conjunction with both orthopedic and vascular surgery were reviewed.
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Sixty-three patients underwent sixty-six surgical resections for STS during the study
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period. There were no perioperative deaths. Fifty-two lower extremity resections (78.8%), six
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upper extremity resections (9.1%), and eight pelvic resections (12.1%) were performed. Sixteen
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cases required a vascular intervention (24.2%). These interventions included bypass in two
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patients (12.5%), primary repair of a named vessel in four patients (25%), and ligation of a
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named vessel in ten patients (62.5%). Three patients had local recurrence of their tumor (4.5%),
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requiring further resection during the follow-up period. Seven patients required a primary
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amputation (10.6%). The average size of tumor removed was 1,776 mL, ranging from 5 mL to
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36,300 mL.
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Conclusion: The quality of surgical resection is paramount in optimal treatment of STS, however,
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wide resection of STS can result in prolonged operative times, significant blood loss, vascular
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complications, and functional deficits. A multidisciplinary surgical team including orthopedic
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and vascular teams may improve treatment by optimizing complex resections that may require
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involved vascular control or reconstruction.
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Introduction Soft tissue sarcomas (STS) are rare tumors accounting for less than 1% of adult tumors
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and are treated primarily with wide surgical resection and local radiation. STS represent a
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heterogeneous group of tumors with multiple histologic subtypes. Each subtype of STS exhibits
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different clinical and cellular behaviors, resulting in differing responses to both local and
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systemic therapies.1,2 While these tumors may occur anywhere in the body, including the
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retroperitoneum and pelvis, STS occur most often in the extremities. Metastasis is most
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commonly found in the lungs and up to 10% of patients present with metastatic disease.3,4
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The most important factor in predicting local recurrence is positive margins on surgical
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excision1-4, therefore adequate resection margins are necessary to achieve optimal local
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treatment. STS often occur adjacent to, or are primarily involved with neurovascular structures
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and thus pose the challenge of achieving negative margins while preserving function. Since the
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inception of adjuvant and neo-adjuvant radiation, reports have shown promising rates of limb
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salvage while also achieving adequate resection margins. However, many of these resections are
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complex and may require extensive vascular dissection or reconstruction.5-10
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Multidisciplinary approaches to the treatment of STS have been previously advocated for,
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and the involvement of a vascular surgical team in the management of STS has been associated
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with decreased morbidity and improved outcomes.7-12 This study was performed to review the
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clinical results achieved following surgical resection of soft tissue sarcomas undertaken by a
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multidisciplinary team, including vascular surgery, orthopedic oncology, radiation oncology, and
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medical oncology teams at a single academic tertiary medical center.
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Methods A retrospective review of the surgical treatment of soft tissue sarcomas at a single
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academic tertiary medical center was performed. All surgical cases for soft tissue sarcoma
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performed in conjunction with both orthopedic and vascular surgery teams at Cooper University
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Hospital between July 1, 2012 and January 31, 2015 were reviewed. Cases with a confirmed
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histologic diagnosis of sarcoma were included. Any cases without a final histologic diagnosis of
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sarcoma were excluded. The Institutional Review Board of Cooper University Hospital reviewed
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this study and approval was waived, as all patient data was de-identified.
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The beginning of the study period marked the institution of a dedicated orthopedic
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oncology center at Cooper University Hospital, establishing a partnership between the
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institution’s Cancer Institute and Bone and Joint Institute. This relationship coincided with the
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addition of a specialized cancer treatment center in partnership with MD Anderson Cancer
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Center, an academic comprehensive cancer program. The multidisciplinary STS team at Cooper
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University Hospital included orthopedic and vascular surgery, as well as team members from the
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departments of medical oncology, diagnostic radiology, interventional radiology, pathology, and
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radiation oncology.
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The aim of vascular surgical intervention in this series was to preserve adequate flow to
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the affected extremity. In patients requiring vascular repair or reconstruction, autologous conduit
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from a non-affected limb was preferred, with plan for extra-anatomic tunneling if bypass was
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needed. Primary amputation of an extremity was reserved for patients that would be left with a
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non-functional limb after adequate resection of the tumor. Patients were seen and evaluated in
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both the orthopedic and vascular surgical offices with appropriate preoperative imaging to
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determine the extent of the disease as well as the likelihood of vascular reconstruction. Those
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patients in whom vascular reconstruction seemed likely also underwent vein mapping of all
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extremities to determine the quality of autologous conduit. The main outcomes reviewed included the type of vascular intervention performed and
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peri-operative mortality. Secondary outcomes reviewed included peri-operative morbidity
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including wound complications, amputation, recurrence, tumor size, operative time, and
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estimated blood loss (EBL).
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A total of 63 patients with 66 surgical resections performed for STS were identified
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during the study period. The indication for a combined orthopedic oncology/vascular surgery
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intervention was the presence of a tumor immediately adjacent to, or directly involving, major
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neurovascular bundles. Most resections performed involved the lower extremity (78.8%), with
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upper extremity and pelvic resections accounting for a much smaller proportion of procedures
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performed (9.1% and 12.1%, respectively). (Table 1) No patients died during the perioperative
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period. Mean procedure time was 155 min, ranging from 27 min to 843 min. The procedure that
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took 843 minutes required a free flap by plastic surgery. Average blood loss was 276 mL,
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ranging from 5 mL to 2,000 mL.Sixteen of the sixty-six resections (24.2%) required vascular
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intervention beyond assistance with exposure and vessel exploration. The most common
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intervention was ligation of a vessel in 10 patients (62.5%). Two patients (12.5%) underwent
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arterial bypass, one femoral to popliteal arterial bypass and one below knee popliteal to posterior
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tibial arterial bypass. Four patients (25%) underwent primary repair of a vessel. (Figure 1) In
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those patients requiring bypass, contralateral reversed great saphenous vein was utilized for the
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reconstruction. The bypasses were tunneled outside of the area of oncologic resection.
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ACCEPTED MANUSCRIPT 7 A total of seven patients underwent primary amputation. This included two hindquarter
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amputations (28.6%), two hip disarticulations (28.6%), two transfemoral amputations (28.6%),
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and one forequarter amputation (14.2%). Three patients experienced local recurrence and
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required further surgery. Two patients with recurrence required repeat wide resections and one
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patient with recurrence required transfemoral amputation. All three patients requiring further
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surgery had large lower extremity sarcomas, two pleiomorphic sarcomas and one soft tissue
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chondrosarcoma. The volumes of these tumors at the time of index resection were 3,740 mL,
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1,805 mL, and 593 mL respectively.
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Eleven patients (17.7%) experienced post-operative wound-related complications. These
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complications were most frequent in patients requiring hip disarticulation (100%) or
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hemipelvectomy (50%). Superficial skin and soft tissue wound infections were the most common
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complication, accounting for 54.5%. One superficial wound complication was related to disease
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recurrence causing skin ulceration that required an above knee amputation. Three deep soft tissue
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infections were observed, accounting for 27.3% of wound complications. Both hip
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disarticulations performed during this study resulted in superficial hip infections and one leg
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resection resulted in a large defect that was unable to be closed and was not a candidate for flap
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coverage that ultimately required an above knee amputation. Other complications included one
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seroma and one rotational flap necrosis. (Figure 2)
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Discussion
Soft tissue sarcomas are a diverse group of malignancies comprising of at least 80
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different subtypes with varying presentations, behaviors, and outcomes. Though a relatively
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uncommon malignancy, accounting for less than 1% of all adult malignancies in the US
ACCEPTED MANUSCRIPT 8 annually, STS represent an aggressive disease with nearly half of all subtypes malignant at
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diagnosis with high metastatic potential, and the remainder of all subtypes acting locally
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aggressive. As for all solid tumors, complete excision with adequate margins is the critical
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surgical tenet for STS.1-4
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Unplanned sarcoma excision, without implementation of necessary surgical margins or
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without appropriate local and systemic staging, can lead to residual disease or contamination of
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surrounding structures, which may portend significantly worse outcomes for the patient.
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Unfortunately, many patients may undergo resection or biopsy before referral to specialized
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treatment centers. Given the heterogeneity of these tumors and the relatively rare nature of the
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disease, most accept that a multidisciplinary setting with specialized oncologic centers is the best
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practice for management of STS, ideally before resection is attempted.3,5,13
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While wide excision with appropriate margins constitutes ideal treatment of STS, this
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may lead to undesirable functional outcomes, especially in extremities. Historically, fully one-
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third of patients with STS of the extremity underwent amputation for curative treatment. The rate
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of primary amputation decreased to 15-20% during the mid-1980s to 1990s as wide resection
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was combined with adjuvant or neo-adjuvant radiation.6 A push towards limb-sparing surgery,
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particularly for STS of the extremity, comes with the added complexity of managing
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neurovascular structures, leading to the inclusion of vascular surgeons in the multidisciplinary
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care of patients with STS.7-12,14
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Experience detailing outcomes with major vascular resection and reconstruction is
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limited with most reports describing small cases series.9,10 Schwarzbach et al. reported their
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experience with 21 patients undergoing vascular resection during excision of extremity STS.
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Eight patients (38.1%) underwent arterial reconstruction only and 12 patients (57.1%) underwent
ACCEPTED MANUSCRIPT 9 combined arterial and venous reconstruction. Of these patients, 57.2% experienced surgical or
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wound morbidity, one-third required reoperation including two patients who needed revision of
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their bypass. One patient died of pulmonary embolism in the peri-operative period, leading to a
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mortality rate of 5%. At the end of the follow-up period, seven (35%) arterial bypasses had
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occluded, resulting in two- and five-year primary patency rates of 58.3%. Venous bypass patency
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was worse, with occlusion occurring in 5 patients (41.7%). However, limb salvage rates were
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good, 94.1% at 5 years, with only one patient requiring a hemipelvectomy due to local
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recurrence in the proximal thigh.7
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Mogannam et al. advocated for early involvement of vascular surgical teams in the
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planning and performance of oncologic resections. They reported their experience in 21 cases
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over a seven-year period. Eleven cases (52%) had pre-operative vascular surgical consultation
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and ten patients had urgent/emergent intraoperative vascular consultation. Complete resection
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was achieved in 10 of 11 cases with pre-operative vascular surgical involvement (91%), while
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only 70% of patients with intraoperative vascular surgical involvement achieved a complete
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resection, though this was not statistically significant. Overall, six patients had vascular injury
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requiring repair, five of which occurred in patients with urgent vascular surgical consultation,
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which was statistically significant (P = .038). Estimated blood loss was also greater in patients
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with urgent vascular consultation, 1,545 mL vs. 436 mL (P = .22). There was a trend towards
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better survival in patients who had preoperative vascular surgical consultation. Additionally, this
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study highlighted the added benefit of exposure to more open cases for vascular surgical trainees
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in an era of increasing endovascular procedures and diminishing open surgical experience.11
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Our results mirror those previously described with a moderate level of surgical morbidity,
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mostly related to wound complications in nearly 18% of the patients in our series. However,
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with adjunctive wound care and antibiotic management. Vascular surgical reconstructions were
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also uncommon, and of the six patients requiring bypass or primary repair of vessels, only one
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patient experienced a wound complication. Patients requiring vascular bypass did have longer
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than average operative times (241 and 351 minutes) but did not experience any perioperative
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complications and were discharged home at postoperative days four and six. The two patients
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undergoing bypass were maintained on aspirin 81mg daily and followed up in the vascular
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surgical office with surveillance duplex of the bypass at 1 month, 3 months, 6 months, then
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annually. To date, both bypasses have remained widely patent without additional intervention.
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Conclusion
STS comprise a heterogeneous yet infrequent malignancy in which the mainstay of
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treatment is complete surgical excision. As the focus of treatment of STS shifts towards
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achieving successful resection with acceptable functional outcomes, as well as high rates of limb
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salvage, it is apparent that a multidisciplinary approach is necessary to achieve this goal.
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Multiple groups have shown improved outcomes with the inclusion of various disciplines in the
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treatment of STS. As multidisciplinary teams become the mainstay for the treatment of STS,
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hospital groups must evaluate who should be included in the treatment team and what role each
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participant should play.
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The inclusion of vascular surgeons as part of the multidisciplinary team, especially in the
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preoperative planning and preparation, has been shown to improve the treatment of soft tissue
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sarcomas by optimizing complex resections that may require involved vascular control or
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reconstruction. Additionally, including vascular surgery as part of the multidisciplinary team
ACCEPTED MANUSCRIPT 11 may provide trainees with a broader open case experience, both for vascular exposures as well as
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for interventions. This review of our institutional experience with a multidisciplinary approach to
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STS after the inception of a dedicated oncologic orthopedic service within a specialized cancer
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treatment paradigm has shown promising outcomes with respect to peri-operative mortality,
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disease recurrence, amputation, and peri-operative morbidity.
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Based on our experience and that of other groups reporting outcomes for STS, we
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recommend a multidisciplinary evaluation of patients undergoing surgical resection of STS that
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includes the involvement of orthopedics, vascular surgery, oncology, pathology, and radiology
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when possible. Additionally, full radiologic evaluation of the patients preoperatively, including
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vein mapping, is important for anticipating the likelihood of vascular surgical reconstruction as
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well as planning the type and location of reconstruction or bypass. Autologous conduit from the
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contralateral limb is preferred, and both arterial and venous reconstructions should be performed
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when feasible. Additionally, we recommend tunneling outside of the area of resection for bypass
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procedures given the rate of wound infection and surgical site complications.
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The limitations of our review include the retrospective nature, short follow-up, and small
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overall number of cases with vascular surgical intervention. Further study is needed to determine
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the added value of specialty surgeons in the multidisciplinary care of STS as well as the value of
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these cases for vascular trainees.
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References
232 [1] Massarweh N, Dickson P, Anaya D. Soft tissue sarcomas: Staging principles and
234
prognostic nomograms. J Surg Onc 2015; 111: 532-9.
235
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[2] Brennan M, Antonescu C, Moraco N, Singer S. Lessons learned from the study of 10,000
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patients with soft tissue sarcoma. Ann Surg 2014; 260: 416-422.
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[3] Kneisl J, Coleman M, Raut C. Outcomes in the management of adult soft tissue sarcomas.
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J Surg Onc 2014; 110: 527-538.
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[4] Coindre J, Terrier P, Gillou L, Le Doussal V, Collin F, Ranchere D, et al. Predictive value of
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grade for metastasis development in the main histologic types of adult soft tissue sarcomas:
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A study of 1240 patients from the French Federation of Cancer Centers sarcoma group.
245
Cancer 2001; 91: 1914-1926.
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[5] Chao A, Mayerson J, Chandawarkar R, Scharschmidt T. Surgical management of soft
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tissue sarcomas: Extremity sarcomas. J Surg Onc 2015; 111: 540-5.
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[6] Williard W, Hadju S, Casper E, Brennan M. Comparison of amputation with limb-sparing
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operations for adult soft tissue sarcoma of the extremity. Ann Surg 1992; 215: 269-275.
252
ACCEPTED MANUSCRIPT 13 [7] Schwarzbach M, Hormann Y, Hinz U, Bernd L, Willeke F, Mechtersheimer G, et al.
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Results of limb-sparing surgery with vascular replacement for soft tissue sarcoma in the
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lower extremity. J Vasc Surg 2005; 42: 88-97.
256
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[8] Emori M, Hamada K, Omori S, Joyama S, Tomita Y, Hashimoto N, et al. Surgery with
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vascular reconstruction for soft-tissue sarcomas in the inguinal region: Oncologic and
259
functional outcomes. Ann Vasc Surg 2012; 26: 693-9.
260
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[9] Muramatsu K, Ihara K, Miyoshi T, Yoshida K, Taguchi T. Clinical outcome of limb-salvage
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surgery after wide resection of sarcoma and femoral vessel reconstruction. Ann Vasc Surg
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2011; 25: 1071-7.
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[10] Song T, Harris J, Raghavan S, Norton J. Major blood vessel reconstruction during
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sarcoma surgery. Arch Surg 2009; 144: 817-822.
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[11] Mogannam A, de Paz C, Sheng N, Patel S, Bianchi C, Chiriano J, et al. Early vascular
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consultation in the setting of oncologic resections: Benefit for patients and a continuing
270
source of open vascular surgical training. Ann Vasc Surg 2015; 29: 810-5.
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[12] McGoldrick N, Butler J, Lavelle M, Sheehan S, Dudeney S, O’Toole G. Resection and
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reconstruction of pelvic and extremity soft tissue sarcoma with major vascular
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involvement: Current concepts. World J Orthop 2016; 7: 293-300.
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[13] Charoenlap C, Imanishi J, Tanaka T, Slavin J, Ngan S, Changer S, et al. Outcomes of
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unplanned sarcoma excision: Impact of residual disease. Cancer Med 2016; 5: 980-8.
278 [14] Muller D, Beltrami G, Scoccianti G, Frenos F, Capanna R. Combining limb-sparing
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surgery with radiation therapy in high-grade soft tissue sarcoma of extremities—Is it
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effective? Eur J Surg Oncol 2016; 42: 1057-1063.
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ACCEPTED MANUSCRIPT 15 Figure Legends
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Figure 1: Intervention Performed
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Figure 2: Wound Complications
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ACCEPTED MANUSCRIPT
Cases
Lower Extremity
Arterial
EBL
Range
Range
(Average) mL3
(Average) mL
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5 – 9,000 (1,174)
5 – 600 (112)
2
720 – 1,155
200 – 1,000
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Tumor Size
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Table 1: All cases performed Location Vascular
(614)
(600)
24 – 2,280 (721)
50 – 550 (250)
Exploration
Primary Repair
4
of Vessel Ligation of
3
Vessel Arterial
3
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Upper Extremity
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Arterial Bypass
Exploration Ligation of
Pelvis
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Vessel
Arterial
3
4
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Exploration
Ligation of
50 – 300 (217)
180 – 3,016
100 – 200 (167)
(1,325) 180 – 3,060
50 – 500 (267)
(1,280) 28 – 11,934
50 – 1,500 (788)
(3,248) 4
Vessel
Total
49 – 1,620 (655)
66
980 – 36,300
600 – 2,000
(9,969)
(1,525)
5 – 36,300
5 – 2,000 (276)
(1,776)
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Table 1: All cases performed Vascular Involvement
Cases
Tumor Size Range (Average) mL3
EBL Range (Average) mL
Lower Extremity
Arterial Exploration Arterial Bypass Primary Repair of Vessel Ligation of Vessel
43 2 4 3
5 – 9,000 (1,174) 720 – 1,155 (614) 24 – 2,280 (721) 49 – 1,620 (655)
5 – 600 (112) 200 – 1,000 (600) 50 – 550 (250) 50 – 300 (217)
Upper Extremity
Arterial Exploration Ligation of Vessel
3 3
180 – 3,016 (1,325) 180 – 3,060 (1,280)
100 – 200 (167) 50 – 500 (267)
Pelvis
Arterial Exploration Ligation of Vessel
4 4
28 – 11,934 (3,248) 980 – 36,300 (9,969)
50 – 1,500 (788) 600 – 2,000 (1,525)
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5 – 36,300 (1,776)
5 – 2,000 (276)
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S0890-5096(18)30485-0
DOI:
10.1016/j.avsg.2018.04.035
Reference:
AVSG 3920
To appear in:
Annals of Vascular Surgery
Received Date: 4 June 2017 Revised Date:
14 April 2018
Accepted Date: 19 April 2018
Please cite this article as: Awad N, Lackman R, McMackin K, Kim TW, Lombardi J, Caputo F, Multidisciplinary Approach to Treatment of Soft Tissue Sarcomas Requiring Complex Oncologic Resections, Annals of Vascular Surgery (2018), doi: 10.1016/j.avsg.2018.04.035. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1 1
Title Page Multidisciplinary Approach to Treatment of Soft Tissue Sarcomas Requiring Complex
3
Oncologic Resections
4
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5
Nadia Awad1, Richard Lackman2, Katherine McMackin1, Tae Won Kim2,
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Joseph Lombardi1, Francis Caputo1
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Division of Vascular Surgery, Department of Surgery
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Cooper Medical School of Rowan University, Camden, NJ 2
Department of Orthopedic Surgery
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Cooper Medical School of Rowan University, Camden, NJ
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Nadia Awad
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5401 Old York Road
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Suite 203
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Philadelphia, PA 19141
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E-mail: [email protected]
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Phone: (215) 456-6178
21
Fax: (215) 456-6204
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ACCEPTED MANUSCRIPT 2 22
Abstract
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Objective: To review the experience and outcome of utilizing a multidisciplinary team, including
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vascular surgery and orthopedic surgery, in the operative treatment of soft tissue sarcomas (STS)
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at an academic, tertiary care hospital.
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27 Methods:
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A retrospective review was performed of all patients who underwent elective STS
30
resection between July 1, 2012 and January 31, 2015, since the addition of a specialized cancer
31
treatment center and a dedicated oncologic division of orthopedic surgery. Surgical cases
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performed in conjunction with both orthopedic and vascular surgery were reviewed.
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33 Results:
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Sixty-three patients underwent sixty-six surgical resections for STS during the study
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period. There were no perioperative deaths. Fifty-two lower extremity resections (78.8%), six
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upper extremity resections (9.1%), and eight pelvic resections (12.1%) were performed. Sixteen
38
cases required a vascular intervention (24.2%). These interventions included bypass in two
39
patients (12.5%), primary repair of a named vessel in four patients (25%), and ligation of a
40
named vessel in ten patients (62.5%). Three patients had local recurrence of their tumor (4.5%),
41
requiring further resection during the follow-up period. Seven patients required a primary
42
amputation (10.6%). The average size of tumor removed was 1,776 mL, ranging from 5 mL to
43
36,300 mL.
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Conclusion: The quality of surgical resection is paramount in optimal treatment of STS, however,
47
wide resection of STS can result in prolonged operative times, significant blood loss, vascular
48
complications, and functional deficits. A multidisciplinary surgical team including orthopedic
49
and vascular teams may improve treatment by optimizing complex resections that may require
50
involved vascular control or reconstruction.
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ACCEPTED MANUSCRIPT 4 51
Manuscript
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Introduction Soft tissue sarcomas (STS) are rare tumors accounting for less than 1% of adult tumors
54
and are treated primarily with wide surgical resection and local radiation. STS represent a
55
heterogeneous group of tumors with multiple histologic subtypes. Each subtype of STS exhibits
56
different clinical and cellular behaviors, resulting in differing responses to both local and
57
systemic therapies.1,2 While these tumors may occur anywhere in the body, including the
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retroperitoneum and pelvis, STS occur most often in the extremities. Metastasis is most
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commonly found in the lungs and up to 10% of patients present with metastatic disease.3,4
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The most important factor in predicting local recurrence is positive margins on surgical
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excision1-4, therefore adequate resection margins are necessary to achieve optimal local
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treatment. STS often occur adjacent to, or are primarily involved with neurovascular structures
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and thus pose the challenge of achieving negative margins while preserving function. Since the
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inception of adjuvant and neo-adjuvant radiation, reports have shown promising rates of limb
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salvage while also achieving adequate resection margins. However, many of these resections are
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complex and may require extensive vascular dissection or reconstruction.5-10
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Multidisciplinary approaches to the treatment of STS have been previously advocated for,
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and the involvement of a vascular surgical team in the management of STS has been associated
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with decreased morbidity and improved outcomes.7-12 This study was performed to review the
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clinical results achieved following surgical resection of soft tissue sarcomas undertaken by a
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multidisciplinary team, including vascular surgery, orthopedic oncology, radiation oncology, and
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medical oncology teams at a single academic tertiary medical center.
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Methods A retrospective review of the surgical treatment of soft tissue sarcomas at a single
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academic tertiary medical center was performed. All surgical cases for soft tissue sarcoma
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performed in conjunction with both orthopedic and vascular surgery teams at Cooper University
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Hospital between July 1, 2012 and January 31, 2015 were reviewed. Cases with a confirmed
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histologic diagnosis of sarcoma were included. Any cases without a final histologic diagnosis of
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sarcoma were excluded. The Institutional Review Board of Cooper University Hospital reviewed
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this study and approval was waived, as all patient data was de-identified.
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The beginning of the study period marked the institution of a dedicated orthopedic
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oncology center at Cooper University Hospital, establishing a partnership between the
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institution’s Cancer Institute and Bone and Joint Institute. This relationship coincided with the
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addition of a specialized cancer treatment center in partnership with MD Anderson Cancer
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Center, an academic comprehensive cancer program. The multidisciplinary STS team at Cooper
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University Hospital included orthopedic and vascular surgery, as well as team members from the
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departments of medical oncology, diagnostic radiology, interventional radiology, pathology, and
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radiation oncology.
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The aim of vascular surgical intervention in this series was to preserve adequate flow to
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the affected extremity. In patients requiring vascular repair or reconstruction, autologous conduit
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from a non-affected limb was preferred, with plan for extra-anatomic tunneling if bypass was
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needed. Primary amputation of an extremity was reserved for patients that would be left with a
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non-functional limb after adequate resection of the tumor. Patients were seen and evaluated in
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both the orthopedic and vascular surgical offices with appropriate preoperative imaging to
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determine the extent of the disease as well as the likelihood of vascular reconstruction. Those
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patients in whom vascular reconstruction seemed likely also underwent vein mapping of all
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extremities to determine the quality of autologous conduit. The main outcomes reviewed included the type of vascular intervention performed and
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peri-operative mortality. Secondary outcomes reviewed included peri-operative morbidity
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including wound complications, amputation, recurrence, tumor size, operative time, and
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estimated blood loss (EBL).
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A total of 63 patients with 66 surgical resections performed for STS were identified
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during the study period. The indication for a combined orthopedic oncology/vascular surgery
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intervention was the presence of a tumor immediately adjacent to, or directly involving, major
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neurovascular bundles. Most resections performed involved the lower extremity (78.8%), with
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upper extremity and pelvic resections accounting for a much smaller proportion of procedures
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performed (9.1% and 12.1%, respectively). (Table 1) No patients died during the perioperative
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period. Mean procedure time was 155 min, ranging from 27 min to 843 min. The procedure that
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took 843 minutes required a free flap by plastic surgery. Average blood loss was 276 mL,
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ranging from 5 mL to 2,000 mL.Sixteen of the sixty-six resections (24.2%) required vascular
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intervention beyond assistance with exposure and vessel exploration. The most common
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intervention was ligation of a vessel in 10 patients (62.5%). Two patients (12.5%) underwent
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arterial bypass, one femoral to popliteal arterial bypass and one below knee popliteal to posterior
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tibial arterial bypass. Four patients (25%) underwent primary repair of a vessel. (Figure 1) In
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those patients requiring bypass, contralateral reversed great saphenous vein was utilized for the
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reconstruction. The bypasses were tunneled outside of the area of oncologic resection.
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ACCEPTED MANUSCRIPT 7 A total of seven patients underwent primary amputation. This included two hindquarter
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amputations (28.6%), two hip disarticulations (28.6%), two transfemoral amputations (28.6%),
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and one forequarter amputation (14.2%). Three patients experienced local recurrence and
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required further surgery. Two patients with recurrence required repeat wide resections and one
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patient with recurrence required transfemoral amputation. All three patients requiring further
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surgery had large lower extremity sarcomas, two pleiomorphic sarcomas and one soft tissue
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chondrosarcoma. The volumes of these tumors at the time of index resection were 3,740 mL,
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1,805 mL, and 593 mL respectively.
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Eleven patients (17.7%) experienced post-operative wound-related complications. These
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complications were most frequent in patients requiring hip disarticulation (100%) or
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hemipelvectomy (50%). Superficial skin and soft tissue wound infections were the most common
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complication, accounting for 54.5%. One superficial wound complication was related to disease
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recurrence causing skin ulceration that required an above knee amputation. Three deep soft tissue
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infections were observed, accounting for 27.3% of wound complications. Both hip
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disarticulations performed during this study resulted in superficial hip infections and one leg
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resection resulted in a large defect that was unable to be closed and was not a candidate for flap
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coverage that ultimately required an above knee amputation. Other complications included one
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seroma and one rotational flap necrosis. (Figure 2)
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Discussion
Soft tissue sarcomas are a diverse group of malignancies comprising of at least 80
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different subtypes with varying presentations, behaviors, and outcomes. Though a relatively
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uncommon malignancy, accounting for less than 1% of all adult malignancies in the US
ACCEPTED MANUSCRIPT 8 annually, STS represent an aggressive disease with nearly half of all subtypes malignant at
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diagnosis with high metastatic potential, and the remainder of all subtypes acting locally
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aggressive. As for all solid tumors, complete excision with adequate margins is the critical
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surgical tenet for STS.1-4
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Unplanned sarcoma excision, without implementation of necessary surgical margins or
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without appropriate local and systemic staging, can lead to residual disease or contamination of
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surrounding structures, which may portend significantly worse outcomes for the patient.
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Unfortunately, many patients may undergo resection or biopsy before referral to specialized
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treatment centers. Given the heterogeneity of these tumors and the relatively rare nature of the
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disease, most accept that a multidisciplinary setting with specialized oncologic centers is the best
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practice for management of STS, ideally before resection is attempted.3,5,13
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While wide excision with appropriate margins constitutes ideal treatment of STS, this
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may lead to undesirable functional outcomes, especially in extremities. Historically, fully one-
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third of patients with STS of the extremity underwent amputation for curative treatment. The rate
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of primary amputation decreased to 15-20% during the mid-1980s to 1990s as wide resection
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was combined with adjuvant or neo-adjuvant radiation.6 A push towards limb-sparing surgery,
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particularly for STS of the extremity, comes with the added complexity of managing
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neurovascular structures, leading to the inclusion of vascular surgeons in the multidisciplinary
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care of patients with STS.7-12,14
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Experience detailing outcomes with major vascular resection and reconstruction is
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limited with most reports describing small cases series.9,10 Schwarzbach et al. reported their
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experience with 21 patients undergoing vascular resection during excision of extremity STS.
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Eight patients (38.1%) underwent arterial reconstruction only and 12 patients (57.1%) underwent
ACCEPTED MANUSCRIPT 9 combined arterial and venous reconstruction. Of these patients, 57.2% experienced surgical or
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wound morbidity, one-third required reoperation including two patients who needed revision of
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their bypass. One patient died of pulmonary embolism in the peri-operative period, leading to a
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mortality rate of 5%. At the end of the follow-up period, seven (35%) arterial bypasses had
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occluded, resulting in two- and five-year primary patency rates of 58.3%. Venous bypass patency
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was worse, with occlusion occurring in 5 patients (41.7%). However, limb salvage rates were
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good, 94.1% at 5 years, with only one patient requiring a hemipelvectomy due to local
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recurrence in the proximal thigh.7
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Mogannam et al. advocated for early involvement of vascular surgical teams in the
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planning and performance of oncologic resections. They reported their experience in 21 cases
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over a seven-year period. Eleven cases (52%) had pre-operative vascular surgical consultation
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and ten patients had urgent/emergent intraoperative vascular consultation. Complete resection
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was achieved in 10 of 11 cases with pre-operative vascular surgical involvement (91%), while
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only 70% of patients with intraoperative vascular surgical involvement achieved a complete
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resection, though this was not statistically significant. Overall, six patients had vascular injury
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requiring repair, five of which occurred in patients with urgent vascular surgical consultation,
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which was statistically significant (P = .038). Estimated blood loss was also greater in patients
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with urgent vascular consultation, 1,545 mL vs. 436 mL (P = .22). There was a trend towards
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better survival in patients who had preoperative vascular surgical consultation. Additionally, this
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study highlighted the added benefit of exposure to more open cases for vascular surgical trainees
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in an era of increasing endovascular procedures and diminishing open surgical experience.11
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Our results mirror those previously described with a moderate level of surgical morbidity,
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mostly related to wound complications in nearly 18% of the patients in our series. However,
ACCEPTED MANUSCRIPT 10 more than half of those complications were superficial wound complications and self-limited
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with adjunctive wound care and antibiotic management. Vascular surgical reconstructions were
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also uncommon, and of the six patients requiring bypass or primary repair of vessels, only one
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patient experienced a wound complication. Patients requiring vascular bypass did have longer
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than average operative times (241 and 351 minutes) but did not experience any perioperative
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complications and were discharged home at postoperative days four and six. The two patients
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undergoing bypass were maintained on aspirin 81mg daily and followed up in the vascular
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surgical office with surveillance duplex of the bypass at 1 month, 3 months, 6 months, then
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annually. To date, both bypasses have remained widely patent without additional intervention.
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Conclusion
STS comprise a heterogeneous yet infrequent malignancy in which the mainstay of
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treatment is complete surgical excision. As the focus of treatment of STS shifts towards
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achieving successful resection with acceptable functional outcomes, as well as high rates of limb
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salvage, it is apparent that a multidisciplinary approach is necessary to achieve this goal.
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Multiple groups have shown improved outcomes with the inclusion of various disciplines in the
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treatment of STS. As multidisciplinary teams become the mainstay for the treatment of STS,
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hospital groups must evaluate who should be included in the treatment team and what role each
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participant should play.
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The inclusion of vascular surgeons as part of the multidisciplinary team, especially in the
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preoperative planning and preparation, has been shown to improve the treatment of soft tissue
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sarcomas by optimizing complex resections that may require involved vascular control or
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reconstruction. Additionally, including vascular surgery as part of the multidisciplinary team
ACCEPTED MANUSCRIPT 11 may provide trainees with a broader open case experience, both for vascular exposures as well as
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for interventions. This review of our institutional experience with a multidisciplinary approach to
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STS after the inception of a dedicated oncologic orthopedic service within a specialized cancer
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treatment paradigm has shown promising outcomes with respect to peri-operative mortality,
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disease recurrence, amputation, and peri-operative morbidity.
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Based on our experience and that of other groups reporting outcomes for STS, we
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recommend a multidisciplinary evaluation of patients undergoing surgical resection of STS that
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includes the involvement of orthopedics, vascular surgery, oncology, pathology, and radiology
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when possible. Additionally, full radiologic evaluation of the patients preoperatively, including
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vein mapping, is important for anticipating the likelihood of vascular surgical reconstruction as
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well as planning the type and location of reconstruction or bypass. Autologous conduit from the
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contralateral limb is preferred, and both arterial and venous reconstructions should be performed
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when feasible. Additionally, we recommend tunneling outside of the area of resection for bypass
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procedures given the rate of wound infection and surgical site complications.
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The limitations of our review include the retrospective nature, short follow-up, and small
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overall number of cases with vascular surgical intervention. Further study is needed to determine
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the added value of specialty surgeons in the multidisciplinary care of STS as well as the value of
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these cases for vascular trainees.
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References
232 [1] Massarweh N, Dickson P, Anaya D. Soft tissue sarcomas: Staging principles and
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prognostic nomograms. J Surg Onc 2015; 111: 532-9.
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[2] Brennan M, Antonescu C, Moraco N, Singer S. Lessons learned from the study of 10,000
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patients with soft tissue sarcoma. Ann Surg 2014; 260: 416-422.
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[3] Kneisl J, Coleman M, Raut C. Outcomes in the management of adult soft tissue sarcomas.
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J Surg Onc 2014; 110: 527-538.
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[4] Coindre J, Terrier P, Gillou L, Le Doussal V, Collin F, Ranchere D, et al. Predictive value of
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grade for metastasis development in the main histologic types of adult soft tissue sarcomas:
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A study of 1240 patients from the French Federation of Cancer Centers sarcoma group.
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Cancer 2001; 91: 1914-1926.
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[5] Chao A, Mayerson J, Chandawarkar R, Scharschmidt T. Surgical management of soft
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tissue sarcomas: Extremity sarcomas. J Surg Onc 2015; 111: 540-5.
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[6] Williard W, Hadju S, Casper E, Brennan M. Comparison of amputation with limb-sparing
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operations for adult soft tissue sarcoma of the extremity. Ann Surg 1992; 215: 269-275.
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ACCEPTED MANUSCRIPT 13 [7] Schwarzbach M, Hormann Y, Hinz U, Bernd L, Willeke F, Mechtersheimer G, et al.
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Results of limb-sparing surgery with vascular replacement for soft tissue sarcoma in the
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lower extremity. J Vasc Surg 2005; 42: 88-97.
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[8] Emori M, Hamada K, Omori S, Joyama S, Tomita Y, Hashimoto N, et al. Surgery with
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vascular reconstruction for soft-tissue sarcomas in the inguinal region: Oncologic and
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functional outcomes. Ann Vasc Surg 2012; 26: 693-9.
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[9] Muramatsu K, Ihara K, Miyoshi T, Yoshida K, Taguchi T. Clinical outcome of limb-salvage
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surgery after wide resection of sarcoma and femoral vessel reconstruction. Ann Vasc Surg
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2011; 25: 1071-7.
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[10] Song T, Harris J, Raghavan S, Norton J. Major blood vessel reconstruction during
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sarcoma surgery. Arch Surg 2009; 144: 817-822.
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[11] Mogannam A, de Paz C, Sheng N, Patel S, Bianchi C, Chiriano J, et al. Early vascular
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consultation in the setting of oncologic resections: Benefit for patients and a continuing
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source of open vascular surgical training. Ann Vasc Surg 2015; 29: 810-5.
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[12] McGoldrick N, Butler J, Lavelle M, Sheehan S, Dudeney S, O’Toole G. Resection and
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reconstruction of pelvic and extremity soft tissue sarcoma with major vascular
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involvement: Current concepts. World J Orthop 2016; 7: 293-300.
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[13] Charoenlap C, Imanishi J, Tanaka T, Slavin J, Ngan S, Changer S, et al. Outcomes of
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effective? Eur J Surg Oncol 2016; 42: 1057-1063.
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ACCEPTED MANUSCRIPT 15 Figure Legends
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Figure 1: Intervention Performed
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Figure 2: Wound Complications
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ACCEPTED MANUSCRIPT
Cases
Lower Extremity
Arterial
EBL
Range
Range
(Average) mL3
(Average) mL
43
5 – 9,000 (1,174)
5 – 600 (112)
2
720 – 1,155
200 – 1,000
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Tumor Size
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Table 1: All cases performed Location Vascular
(614)
(600)
24 – 2,280 (721)
50 – 550 (250)
Exploration
Primary Repair
4
of Vessel Ligation of
3
Vessel Arterial
3
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Upper Extremity
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Arterial Bypass
Exploration Ligation of
Pelvis
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Vessel
Arterial
3
4
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Exploration
Ligation of
50 – 300 (217)
180 – 3,016
100 – 200 (167)
(1,325) 180 – 3,060
50 – 500 (267)
(1,280) 28 – 11,934
50 – 1,500 (788)
(3,248) 4
Vessel
Total
49 – 1,620 (655)
66
980 – 36,300
600 – 2,000
(9,969)
(1,525)
5 – 36,300
5 – 2,000 (276)
(1,776)
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Table 1: All cases performed Vascular Involvement
Cases
Tumor Size Range (Average) mL3
EBL Range (Average) mL
Lower Extremity
Arterial Exploration Arterial Bypass Primary Repair of Vessel Ligation of Vessel
43 2 4 3
5 – 9,000 (1,174) 720 – 1,155 (614) 24 – 2,280 (721) 49 – 1,620 (655)
5 – 600 (112) 200 – 1,000 (600) 50 – 550 (250) 50 – 300 (217)
Upper Extremity
Arterial Exploration Ligation of Vessel
3 3
180 – 3,016 (1,325) 180 – 3,060 (1,280)
100 – 200 (167) 50 – 500 (267)
Pelvis
Arterial Exploration Ligation of Vessel
4 4
28 – 11,934 (3,248) 980 – 36,300 (9,969)
50 – 1,500 (788) 600 – 2,000 (1,525)
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5 – 36,300 (1,776)
5 – 2,000 (276)
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