Scapular and Parascapular Free Tissue Transfer

Updated: May 20, 2021
Author: Jason H Kim, MD, FACS; Chief Editor: Arlen D Meyers, MD, MBA 



The scapular/parascapular system of flaps is a unique system of flaps available for free tissue transfer based on the subscapular artery and its branches. In 1978, Saijo was the first to describe the scapular fasciocutaneous flap anatomy based on the circumflex scapular artery (CSA).[1] In the 1980s, dos Santos extensively studied the vascular supply of the free scapular flap in cadavers, contributing to the acceptance and use of free scapular flaps.[2, 3]

In a 1981 article, Teot et al identified the lateral border of the scapula bone as a potential source of vascularized bone based on periosteal branches of the circumflex scapular artery (CSA).[4] In 1986, Swartz et al popularized this particular flap in head and neck reconstruction.[5] In 1991, Coleman and Sultan identified the angular artery as the reliable blood supply to the scapular tip, allowing for 2 separate segments of bone to be harvested and improving the reliability of the scapular tip when harvested as a single segment.[6]

In 1984, Batchelor and Sully were the first to describe the incorporation of the latissimus dorsi muscle with the scapular/parascapular flap for reconstruction of a scalp defect.[7] Now, different combinations of the skin, muscle, and bone can be harvested to fit the reconstructive needs.


Evaluation of the patient for consideration of a scapular/parascapular donor site includes an examination of the back and shoulder to rule out significant shoulder morbidity, scarring of the skin in the region, and any signs of vascular insufficiency. Previous axillary lymph node dissection calls into question the viability of the vascular supply to this flap and would preclude the use of this donor site.


The scapular/parascapular flap is the donor site of choice for complex 3-dimensional defects of the head and neck given the amount and variability of tissue types available for harvest.[8, 9] It is excellent for through-and-through oromandibular defects, which require tissue for intraoral and external skin lining, as well as bone. The scapular/parascapular flap is also ideal for defects that require a significant volume or bulk replacement. Up to 14 cm of bone can be harvested from the lateral border of the scapula bone. According to a 1993 report by Frodel et al and a 1994 report by Moscoso et al, the bone stock can be sufficient for the placement of osseointegrated implants and subsequent dental restoration, particularly in male patients.[10, 11] This donor site should also be considered when a fibula free flap is contraindicated because of inadequate collateral circulation, vascular insufficiency, or pitting edema to the lower extremity.

The scapular/parascapular system of flaps is also useful in reconstructing complex midface defects, which require skin or muscle for intraoral lining, external soft tissue coverage, or sinus cavity obliteration, as well as bone for alveolar reconstruction and globe support.[12, 13, 14, 15] Scalp defects can be reconstructed using fasciocutaneous scapular/parascapular flaps of the dorsal thoracic fascia with a split-thickness skin graft. Moreover, complex defects that involve the skull base, orbit, and midface can be restored with a single composite flap that provides bone for the maxilla or orbit, skin for an external cutaneous defect, and latissimus dorsi/ serratus anterior muscle for the skull base defect to provide support for the brain and separation of the dura from the nasal cavity and pharynx.[16, 17]

In addition, Fairbanks and Hallock (2002) reported on using the medial border of the scapula bone along with the lateral border for more complex oromandibular and maxillofacial reconstruction.[18] The lateral border and angle of the scapula was based on the angular artery and the medial border on the distal branches of the circumflex scapular artery (CSA).

Relevant Anatomy

The scapular/parascapular system of flaps is based on the subscapular artery and vein, branches of the third part of the axillary vessels. The advantage of this donor site is the various tissue types available for harvest, allowing tissue to be tailored to complex defects of the head and neck. Moreover, the vessels of the trunk are less commonly involved by atherosclerotic changes. A number of different flaps can be harvested on a single pedicle, and any combination of these flaps may be harvested, depending on the needs of the defect.

Flaps based on the subscapular arterial system include the following:

  • Scapular/parascapular fasciocutaneous flap

  • Scapular/parascapular osteocutaneous flap

  • Latissimus dorsi muscle flap

  • Latissimus dorsi musculocutaneous flap

  • Serratus anterior muscle flap

  • Serratus anterior musculocutaneous flap

  • Dorsal thoracic fascia flap

The subscapular artery has a number of branches that are critical to the understanding of this system of flaps. The 2 major branches of the subscapular artery include the circumflex scapular artery (CSA) and the thoracodorsal artery (TDA). The circumflex scapular artery (CSA) runs through the muscular triangular space and branches into transverse and descending cutaneous branches, which form the basis of the scapular and parascapular fasciocutaneous flaps.[19, 20]

The circumflex scapular artery (CSA) also has periosteal branches, which supply the lateral aspect of the scapular bone except the tip of the scapula. The scapular tip can be supplied by either the circumflex scapular artery (CSA) or the angular branch of the TDA or serratus anterior branch. Two venae comitantes accompany the circumflex scapular artery (CSA) and drain into the thoracodorsal vein; however, the venous anatomy is variable. The TDA runs deep to the teres major and has a number of critical branches that are important in the understanding of this donor site. The angular branch that supplies the tip of the scapular bone is important and must be preserved in order to successfully transfer this portion of bone.[6] The branch to the serratus anterior also arises from the TDA. The distal portion of the TDA terminates into vertical and transverse branches, which supply the latissimus muscle and overlying skin.

The lateral aspect of the scapula bone is available for harvest based on the periosteal branches of the circumflex scapular artery (CSA). Approximately 10 cm of bone is available for harvest in females, and 14 cm of bone is available in males.[5] The tip of the scapular bone is supplied by the angular artery, which has a variable branching pattern.[6, 21] It usually arises as a branch of the TDA or as a branch of the main serratus collateral.[21] This allows the harvest of 2 separate segments of bone from the lateral aspect of the scapula.


Positioning patients who are obese for flap harvest may prove difficult and preclude the use of this donor site. Also, previous axillary lymph node dissection calls into question the viability of the vascular supply to this flap and would preclude the use of this donor site. Moreover, if simultaneous neck dissection is performed, further postoperative shoulder dysfunction needs to be considered.

The only possible limiting factor in the use of this versatile flap may be the length of harvestable bone. Reconstructing the entire mandible is not feasible; neither is angle-to-angle reconstruction. This may also be related to the number of osteotomies that can be made safely on the bone to contour to the native mandible. Also, some concerns have been raised over the potential implantability of these bones, especially in female patients.



Imaging Studies

Imaging and vascular studies are not indicated in the preoperative assessment. However, if atherosclerotic disease or the caliber of the arteries is a concern, angiography can assist in the evaluation. However, this is rare.



Surgical Therapy

Several patient-related factors should be taken into account when considering a patient for microvascular free tissue transfer. Existing comorbidities, such as severe cardiovascular disease, diabetes mellitus, coagulopathies, polycythemia, and sickle cell disease, may pose significant challenges to the reconstructive efforts, and alternative reconstructive options should be equally considered.

Patients who are obese also present unique reconstructive challenges. The amount of subcutaneous fat present may pose problems for particular locations such as the floor of the mouth or external defects. Harvesting fascia rather than full-thickness soft tissue in these patients may be necessary in order to minimize bulk.[22, 23] In addition, positioning these patients for flap harvest may also prove extremely difficult and prevent the use of this donor site.

Preoperative Details

Positioning the patient is critical to the harvest of this flap. The patient needs to be positioned in the lateral decubitus position. Harvesting from the nondominant arm is preferable to reduce postoperative morbidity, although the flap is usually harvested from the same side as the neck dissection. A vacuum beanbag is required to maintain patient position during the harvest. An axillary roll is required to reduce traction on the opposite brachial plexus. The back and arm of the donor site should be prepared at the same time as the extirpative site. Simultaneous extirpation and harvest is tenuous at best and usually cannot be achieved.

Intraoperative Details

The harvest is begun by first identifying the muscular triangular space, as previously described. This can be done by palpation; however, a Doppler probe can be used to localize the circumflex scapular artery (CSA) as it enters the triangular space, thus confirming its location. An assistant is needed to hold the arm, keeping the humerus abducted and the teres major and minor under some tension.

Elliptical cutaneous skin paddles can be designed to suit the needs of the defect. The parascapular flap is taken along the axis of the lateral border of the scapula corresponding with the descending branch of the circumflex scapular artery (CSA). The scapular flap is designed along the horizontal plane almost perpendicular to the lateral border of the scapular bone and corresponds to the transverse branch of the circumflex scapular artery (CSA). A portion of the cutaneous portion of the flap must overlie the triangular space to ensure capturing the circumflex scapular artery (CSA) and its branches.

The superior limit of the harvest is the scapular spine; the inferior limit is the tip of the scapula. Care must be taken when traversing the midline in an attempt to harvest additional skin because this portion is less reliable. The width of the skin paddles and the amount of tissue harvested should obviously suit the needs of the defect. Flap elevation proceeds from medial to lateral in a plane just superficial to the fascia of the infraspinatus, rhomboid, and trapezius muscles. Dissection can also be carried out in the subfascial plane. However, identifying the superior border of the teres major muscle and following it toward the triangular space to avoid injuring the circumflex scapular artery (CSA) and its branches is important.

If scapular bone is to be harvested, the circumflex scapular artery (CSA) is first identified and the teres major muscle divided. This provides the exposure necessary to identify the lateral border of the scapula, the TDA, and possibly the angular artery, which may need to be preserved if the scapular tip is to be harvested in continuity or used as a separate segment of bone.

The muscular branches of the circumflex scapular artery (CSA) must be taken during this part of the harvest. The periosteal branches are taken if a fasciocutaneous flap is to be harvested. With the vascular pedicle identified, the bone can be harvested. An incision is made parallel to the lateral border of the scapular bone through the teres major, teres minor, and infraspinatus muscle. Osteotomies can now be performed using a reciprocating or sagittal saw. Take care to stay at least 1 cm below the glenoid fossa to preserve joint integrity. At this point, the attachments of the subscapularis muscles can be severed to mobilize the bone segment. The vascular pedicle is then traced to its takeoff from the axillary artery.

Primary closure of the donor site can usually be achieved and may require a significant amount of undermining. Use of a split-thickness skin graft in this dependent area is less desirable and should be avoided. The teres major muscle should be approximated to the cut end of the infraspinatus muscle or the cut end of the scapular bone via drill holes. Take care to achieve meticulous hemostasis to avoid postoperative hematoma. Large-bore suction drains should be used for several days postoperatively to minimize hematoma and seroma formation.

Osteotomies can be made in order to contour the bone flap to the reconstruction plate. Take care to preserve overlying periosteum and muscle at the osteotomy site by creating subperiosteal tunnels with a freer prior to making osteotomies. The bone flap can then be secured to the reconstruction plate with the appropriate monocortical screws. Skin flaps can then be inset according to the needs of the defect. Microvascular anastomosis can be performed before or after insetting the flap, based on the surgeon's preference and experience.

In cases in which skin is needed for intraoral and external lining, draping the cutaneous portion of the flap over the bone flap may be necessary. Take care to avoid excess tension on the skin flap as it courses over the bone because venous outflow problems for the external component of the flap can result. This can be avoided by harvesting skin flaps of appropriate size and length for the defect.

Postoperative Details

Postoperatively, the donor arm should be immobilized in an arm sling for about 5 days. Physical therapy can then be instituted to improve passive and active range of motion. Intensive home physical therapy to improve shoulder strength can begin within 3 weeks after surgery. This greatly limits postoperative morbidity.

Postoperative monitoring of flap vascular flow with serial examination, external Doppler, pinprick, or an implantable Doppler device is at the discretion of the reconstructive surgeon. Use of anticlotting agents such as heparin, aspirin, and dextran are also used at the judgment of the surgeon and are not detailed here.


A number of potential complications are associated with the use of the scapular/parascapular donor site. Early complications include hematoma formation, which can result from inadequate hemostasis or coagulopathy. Seroma formation can develop given the amount of dead space present after harvest. Maintaining large suction drains for several days postoperatively helps to alleviate this problem. Wound dehiscence and skin breakdown at the donor site can also develop. This is particularly problematic with large defects that are closed under tension.

Significant undermining of adjacent tissue may be required to obtain primary closure. Skin grafting in this dependent mobile area should be avoided. Wound infection is a rare complication. Use separate instruments and clean gloves and gowns at the donor site to avoid contamination and subsequent wound infection. The donor site is closed prior to working on the recipient site. Antibiotic prophylaxis should be used.

Take care to avoid injury to the long thoracic nerve, which supplies the serratus anterior, because this can result in a winged scapula. Injury to the brachial plexus has been reported with the harvest of the latissimus flap secondary to arm positioning during harvest.[24, 25] Similar injuries can be observed with scapular flap harvest because patient positioning is similar. Take care to avoid extreme elevation of the arm, and support for the head should be provided during harvest.

Few studies have looked at donor site morbidity related to the harvest of the scapular flap. In a 1989 report, Sullivan et al evaluated range of motion and shoulder strength in 12 patients who underwent scapular osteocutaneous free tissue transfer.[26] In the initial postoperative period, shoulder strength and range of motion were significantly affected. Most patients had return of arm flexion and abduction, and all were subjectively satisfied with their level of function. In 2000, Coleman et al addressed donor site morbidity in 5 patients who underwent objective testing, as well as evaluation by questionnaire.[27] This group showed only minor limitations in strength and range of motion.

A study by Ferrari et al found that harvesting of scapular tip free flaps for head-and-neck reconstruction produced very low shoulder morbidity and did not impact patients’ performance of daily activities. The study, which involved 19 patients, reported minimal complications and ambulation times of 2-4 days. Assessment of long-term shoulder function morbidity via Constant-Murley and DASH (Disabilities of the Arm, Shoulder and Hand) scores also demonstrated good results.[28]

Similarly, a prospective cohort study by Patel et al indicated that scapular free flap harvesting does not result in significant shoulder morbidity. The study’s patients, who underwent scapular tip or lateral border scapular free flap surgery, did demonstrate reduced range of motion and strength for shoulder abduction, shoulder flexion, and external rotation. However, there was no significant change in range of motion for shoulder extension. Moreover, subjective measures of shoulder disability—specifically, the Neck Disability Index and Shoulder Pain and Disability Index—revealed no significant effect from the surgery.[29]

Outcome and Prognosis

The scapular/parascapular donor site is unsurpassed in the variability of tissue available for reconstructing complex defects of the head and neck, particularly through-and-through oromandibular and large palatomaxillary defects.[30, 31] Bone, skin, fascia, and muscle are available to the reconstructive surgeon. The ease of harvest, reliability, and limited morbidity associated with the use of this flap make it a desirable donor site in select patients. The disadvantages are few, including the need for repositioning the patient, lack of sensation in the flap, and limited bone stock for osseointegration, particularly in females. Every reconstructive surgeon should be familiar with this important donor site for head and neck reconstruction.

A retrospective study by Wolfer et al found that scapular free flaps can successfully be used in mandibular reconstruction after resection of oral squamous cell carcinoma. The investigators reported that out of 119 such mandibular reconstructions, only 4.2% of the flaps were lost. The reconstructions proved to be just as effective in older patients as in younger ones, with individuals aged 70 years or older experiencing no flap loss.[32]

A study by Song et al indicated that preexpanded scapular free flaps are effective in the reconstruction of neck contracture deformities caused by severe burns, with the investigators reporting significant improvement in neck range of motion. In the study, which included 12 flaps, only one donor site required skin grafting, with the rest closed directly.[33]