Introduction
Originally introduced by Dr Yang and Dr Gao at the Shenyang Military Hospital in the early 1980s, the radial forearm free flap has since been popularized as a workhorse flap. Though generally raised as a fasciocutaneous flap, the radial forearm is extremely versatile. It can also be harvested as an adipofascial flap or with bone from the radius as an osteofasciocutaneous flap. Many studies have demonstrated the benefits of the radial forearm flap in intraoral reconstruction.[1][2][3][4][5] The osteocutaneous radial forearm free flap (OCRFFF) is commonly used in head and neck reconstruction. It is a good option for bony reconstruction of the mandible or midface.[6]
The osteocutaneous radial forearm flap is a variant of the fasciocutaneous radial forearm free flap wherein a partial radius thickness is harvested and perfused by preserving the lateral intermuscular septum and the perforating vessels to the bone. Alternatives to this flap include the osteocutaneous fibular free flap, osteocutaneous scapular free flap, and the osteocutaneous iliac crest free flap. The advantages of the osteocutaneous radial forearm free flap are its skin paddle thinness, pliability, long vascular pedicle, and reliable vascular anatomy. The disadvantages of this flap center around the donor site morbidity relative to the size and quality of bone available for harvest. The osteotomized bone is at risk of fracture and causes reduced strength and function in the operated wrist. This topic discusses the procedure's details and the risks and benefits of using this flap to facilitate its thoughtful utilization.
Anatomy and Physiology
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Anatomy and Physiology
The arterial supply for the osteocutaneous radial forearm flap is the radial artery. The radial artery and the ulnar artery arise from the bifurcation of the brachial artery within the antecubital fossa. This bifurcation is the uppermost limit where the artery can be taken for microvascular anastomosis without compromising the distal extremity. The average diameter of the artery at that point is about 3 mm. The average length of the pedicle ranges between 14 cm and 22 cm in an adult. The vascular pedicle of the free flap sits in the lateral intermuscular septum between the brachioradialis muscle and the flexor carpi radialis. The flap's skin paddle is centered over the distal one-third of the lateral forearm, wherein lie the fasciocutaneous perforators from the radial artery to the skin paddle. The periosteal feeding vessels from the radial artery to the radius lie within the lateral intermuscular septum, and it is important to avoid disrupting the architecture of the septum to ensure the harvested bone has an adequate blood supply.
Patient candidacy for this flap is determined by the viability of the distal extremity (ie, the hand and digits) with only the ulnar artery supplying it. The radial artery ends in the distal wrist, entering the hand as the deep palmar arch. The ulnar artery ends in the distal wrist as the superficial palmar arch. The flow between the superficial and deep palmar arches connects the blood supply from the radial and ulnar arteries in the hand. Several different patterns of vascular anastomosis between the superficial and deep palmar arches have been described.[7][8][9] Generally speaking, if the palmar arch system is complete, the distal extremity can survive on either the radial artery or ulnar artery alone. Suppose the arch is incomplete or the distal extremity depends primarily on arterial inflow from the radial artery (eg, in the case of traumatic transection of the ulnar artery). In that case, the harvest of a radial forearm free flap might result in an ischemic hand, and the flap is contraindicated.
Various clinical tests can be performed to assess the viability of the distal extremity on ulnar arterial flow alone.[10][11][12] The Allen test is the simplest (see Video. Modified Allen Test). The hand is elevated and clenched for 30 seconds, then the radial and ulnar arteries are compressed. The palm is opened and should appear blanched. Ulnar artery compression is released (while maintaining radial artery compression), and the palm is assessed for a speedy return of color. If the palm, thenar eminence, and fingers return to their natural color within 5 seconds, the palmar arch is complete, and the hand can survive on ulnar arterial flow only. A more sophisticated test would be an Allen test with an oximeter on the thumb (most distal from the ulnar artery) to assess the waveform after the release of ulnar artery compression. If the waveform on the oximeter is dampened or delayed after the ulnar artery release, it may suggest an incomplete arch. Another useful test is an upper extremity Doppler study with compression of the radial and ulnar arteries. If raising an OCRFFF poses an ischemic threat to the distal extremity, an alternative reconstruction should be considered.
The primary venous drainage of the flap is provided by paired venae comitantes that run with the radial artery in the deep venous system of the flap between the brachioradialis muscle and the flexor carpi radialis. The skin paddle may drain through a superficial venous plexus into the cephalic vein. This superficial system lies superficial to the brachioradialis muscle and often joins the deep system just distal to the antecubital fossa. The venous system may be harvested and anastomosed as a single system or split into primary (deep) and secondary (superficial) systems to drain the flap. These separate systems allow for using 1 single or 2 independent drainage systems in the neck (eg, facial and external jugular veins). The typical length of the venous pedicle is about 18 to 20 cm.
The superficial branch of the radial nerve is a sensory nerve that provides cutaneous innervation to the thumb and dorsal hand and is a consistent landmark in radial forearm flap harvest. It is important to identify this nerve to reduce morbidity. The nerve is identified in the distal wrist during the elevation of the skin paddle along the radial/lateral aspect. The identity of the nerve can be confirmed by tracing it back to where it emerges from the brachioradialis muscle. It is common to have some degree of cutaneous anesthesia around the thumb postoperatively due to intraoperative manipulation of sensory nerve branches from the superficial branch of the radial nerve entering the skin paddle. However, long-term numbness of the thumb results from a technical error intraoperatively.
The lateral antebrachial cutaneous nerve provides sensation to the lateral half of the volar forearm. This nerve is usually transected, with little consequence, because the skin it innervates is harvested as the skin paddle. However, the nerve can provide a sensate flap at the recipient site.
A large skin paddle can be harvested, but it, too, has limitations. Nearly all the forearm skin can be harvested and supplied by the radial artery, but doing so would significantly alter the lymphatic drainage of the hand. A 3-5 cm wide strip of skin should be preserved on the posterior extensor compartment to avoid lymphedema in the hand. Up to 30 cm of skin can be harvested along the length of the forearm, with a maximum width of about 15 cm. Primary closure can be achieved with skin paddle widths of 1-2 cm. Most OCRFFFs harvested for head and neck reconstruction have skin paddles too large for primary closure of the harvest site defect and generally require a skin graft.
Additionally, when harvesting an osteocutaneous radial forearm free flap instead of a fasciocutaneous flap, it is important to preserve the distal forearm skin at the level of the styloid process of the radius to minimize the chance of hardware complications after the radius is plated. With the fasciocutaneous flap, the distal forearm incision is made within a crease distal to the styloid process of the radius. In the osteocutaneous version of the flap, the distal incision should be placed on the forearm 1-2 cm more proximal. Alternatively, the incision may be placed in the crease, and the pronator quadratus muscle may be used as a flap to cover the distal plate.
One of the disadvantages of OCRFFF harvest is donor site morbidity, the magnitude of which correlates with the size and quality of the harvested radius. The radius is critical to the wrist and hand function. The length of harvestable bone is limited to 10-12 cm, depending on where the pronator teres muscle inserts on the radius. This muscle can be released at its insertion point to gain additional bone length. However, doing so increases the risk of postoperative morbidity, especially with the flexor digitorum, flexor pollicis longus, and pronator quadratus already being incised to harvest bone. If it must be disrupted, the pronator teres should be resuspended from the reconstruction plate after bone harvest. The partial thickness segment of the radius harvested is generally limited to 40-50% of the cross-sectional area of the bone.[13] The amount of bone that can be harvested varies on a case-by-case basis. Like the rest of the skeleton, the radius responds to mechanical stimuli; patients with heavy-loading stimuli to the radius (eg, weight lifting, manual labor, youth versus older age) may have larger and stronger bones.[14] The amount of bone that can be surgically harvested from an active, tall 50-year-old male patient with occupational or recreational demands may differ greatly from a 75-year-old, short female patient.
Biomechanical studies have investigated the effect of partial radial ostectomy in the context of the OCRFFF. One study demonstrated that, compared to an intact cadaveric human radius, the radius that remained after partial-thickness harvest had a breaking strength of 24% that of the control group.[15] Another study on sheep tibias looking at torsional strength demonstrated that ostectomized bone strength was decreased by 70%.[16] A 1990 study with 17 osteocutaneous radial forearm flaps quoted a fracture rate of 23.5%.[17] That study advocated boat-shaped osteotomy over right-angled cuts to reduce fracture incidence. A cadaver study 2000 looked at the biomechanics of prophylactically plating the radius after ostectomy/bone harvest. Right-angled osteotomies were done. They found that adding a reconstruction plate significantly strengthened the ostectomized radius to torsion and bending. Since that study, prophylactic plating has become the standard, with several series showing a significantly lower fracture rate.[18][19][20][21][20] A 2013 study by the same group that first advocated prophylactic plating reviewed their series of 167 consecutive osteocutaneous radial forearm flaps, all plated after ostectomy, and had just 1 fracture.[22]
Indications
The most common indication for osteocutaneous radial forearm free flap is the osseous reconstruction of the mandible and maxilla. The amount of radial bone harvested is generally limited. It is best used in short-segment mandibular and maxilla reconstruction, but its thickness is insufficient for dental implant placement. Similarly, the osteocutaneous radial forearm can augment bone in the extremities, but the thin bone stock limits its use.[23] The OCRFFF has been used in nasal reconstruction, frontal sinus reconstruction, and airway reconstruction.[24] It has also more recently been used in phalloplasty.[25][26][27][28]
Contraindications
Contraindications to microvascular surgery, in general, apply to patients being considered for osteocutaneous radial forearm free flap reconstruction. Contraindications specific to the OCRFFF include the following:
- High risk of distal extremity ischemia with blood supply from the ulnar artery only.
- High risk of flap failure due to an insufficient radial artery.
- Inability to support a free flap with recipient site blood vessels.
- Inability to reconstruct the defect with 10 to 12 cm of bone.
- The requirement to place dental implants into the transferred bone.
As discussed in a previous section, the harvest of the OCRFFF also includes the harvest of the radial artery. After the harvest of the radial forearm free flap, the remaining blood supply to the hand is based solely on the ulnar artery and the network of collateral flow between the superficial and deep palmar arch. The absence of ulnar artery inflow (eg, traumatic injury, profound peripheral vascular disease, arterial agenesis) or the suggestion of an incomplete arch are contraindications to harvesting the OCRFFF. Likewise, insufficient blood flow in the radial artery is a contraindication to using the radial forearm free flap. Example etiologies of arterial insufficiency include injury to the radial artery (eg, trauma, peripheral vascular disease), congenital absence of the vessel, and thromboembolic or hypercoagulable states. The flap is not viable if the radial artery is damaged or absent due to these conditions.[29]
If the flap can be harvested, the recipient site must be able to receive the flap. Several arteries in the neck are suitable for microvascular anastomosis, including branches of the external carotid system and the thyrocervical trunk vessels. If the neck is depleted of these vessels, one can turn to the contralateral neck because of the length of the vascular pedicle. If both necks are vessel-depleted, the internal mammary artery can be dissected and rotated superiorly into the neck to serve as a recipient's vessel. Suppose using the internal mammary artery is the primary reconstructive option to perfuse the OCRFFF. In that case, patient health and other factors may suggest aborting free flap reconstruction in favor of a regional flap, such as the pectoralis major flap or a construct using a plate wrapped with soft tissue.
The size and quality of the bone harvested are also significant limiting factors in using this flap. Reconstructions that require more than 10 to 12 cm of bone, such as a total mandibulectomy, cannot be reconstructed with a single OCRFFF. The thickness of the bone is also limited. Under optimal conditions, the fibular-free flap is preferred for bony reconstructions. It offers many of the same qualities as OCRFFF; it is pliable, thin, and has a long pedicle. However, it has the added advantage of greater bone stock thickness, and most lower extremity weight-bearing is on the tibia, not the fibula. The fibular free flap similarly requires that blood flow to the distal extremity (ie, the foot) be sufficient after the loss of the contribution of the peroneal artery. This might not be a major issue in a young trauma patient needing osseous free flap reconstruction. However, head and neck cancer patients, who may have smoking-related vasculopathy, be older, and may have other medical comorbidities, may have insufficient blood flow to the distal extremity (or through the peroneal artery) to support the fibular flap as a viable reconstruction option. It is not uncommon for a vascular study to contraindicate the use of the fibular flap, leaving the osteocutaneous radial forearm, scapular/parascapular flaps, or iliac crest flap as the next option. Each of these reconstructive options has advantages and disadvantages associated with it.
Patients with previous trauma to the wrist and prior wrist surgeries should be approached carefully. However, a history of wrist surgery is not an absolute contraindication to using the OCRFFF. As flap harvest can alter manual dexterity, the author prefers to harvest from the non-dominant hand. However, due to vascular considerations, the preoperative assessment may favor raising the flap from the dominant arm. The need to harvest a flap from the dominant upper extremity could be considered a relative contraindication in the eyes of the surgeon. Similarly, occupations and hobbies requiring manual dexterity can be considered relative contraindications to this procedure.
Other patients may have medical comorbidities that increase their risk for flap failure. These include but are not limited to, severe peripheral vascular disease, coagulopathies, and cardiovascular disease. Patients with severe peripheral vascular disease present a higher risk of flap failure due to vessel stenosis, intimal disease, poor vessel pliability, baseline inflammatory state, and hypercoagulability. Patients with hypercoagulable pathologies, such as Factor V Leiden thrombophilia, also present an increased risk of flap failure with thrombosis of the vessel anastomosis or clotting within the microcirculation of the flap itself. Smokers also have an elevated risk of microvascular free flap failure. Nonetheless, patients with these conditions have frequently undergone successful microvascular reconstructive procedures.
Cancer patients with multiple, severe medical comorbidities may not be healthy enough to undergo lengthy microvascular operations and may opt for alternative reconstructive options instead. For patients with multiple medical comorbidities, the risks and benefits of microvascular reconstruction may need to be weighed against a functionally or cosmetically suboptimal but lower-risk (and perhaps more reliable) pedicled flap. An example would be a mandibular reconstruction bar wrapped with a pectoralis myofasciocutaneous flap.
Equipment
The following equipment is needed:
- Soft tissue set
- Microvascular set
- Operating microscope
- Surgeon preference osteotomy instruments
- Tourniquet (optional)
- Instruments for prophylactic plating of the radius (strongly recommended)
Personnel
Essential personnel for this procedure include the primary surgeon, 1 or 2 surgical assistants, a circulating/operating room nurse, a surgical technologist, and an anesthesiologist experienced in general anesthesia for lengthy, microvascular surgical cases.
Preparation
The patient is intubated, and the airway is secured. The flap is harvested under general anesthesia.
Allen Test
An Allen test is performed on the extremity from which the flap is harvested. The arm is elevated, and the palm is blanched by informally exsanguinating the hand and quickly applying pressure to the ulnar and radial arteries. Ulnar artery compression is released with the palm blanched, and palmar rubor is evaluated. If the palm turns pink or red within 5 seconds, it suggests a complete palmar arch supporting the distal extremity on ulnar artery blood flow alone. The Allen test is best performed when the patient is warm; if the patient is cold, the hand's perfusion may appear worse than it is.
The author also prefers to use the Doppler as an adjunct to the Allen test, especially if the refill to the palm is sluggish. This test is ideally performed with 2 people. The assistant uses the Doppler on the palm to confirm a distal extremity pulse. The surgeon then compresses the ulnar and radial arteries, and the Doppler should go silent due to a lack of arterial inflow. The ulnar artery is then released, and the Doppler signal should resume with the pulse. If there is no pulse return, the radial artery should be tested by confirming a pulse on the hand with a compressed ulnar artery. Suppose the Doppler detects a pulse on the distal extremity with a compressed ulnar artery. In that case, the radial artery predominantly supplies the hand, and the radial forearm flap harvest should be aborted in favor of another reconstructive option. One disadvantage of this method is that it cannot detect the rare instance of an incomplete superficial palmar arch. The Doppler should be used with the Allen test to confirm the signs of capillary refill to the entire hand from the ulnar artery alone. If there is concern about the ability of the distal extremity to rely solely on the ulnar artery, the flap should be aborted in favor of a different reconstructive option.
Patient Positioning
As most osteocutaneous radial forearm free flaps are used in head and neck reconstruction, the patient is usually supine with the patient’s head at the top edge of the bed. The neck is generally extended with a shoulder roll, and 1 or 2 belt straps are used to secure the patient to the bed. The arm from which the flap is harvested is untucked and placed on an arm board. The author prefers to harvest the flap on a pivoting arm board instead of a hand surgery table when the free flap is harvested for head and neck reconstruction. The arm board has a smaller, slimmer profile, which reduces the displacement of the ablative surgeon or assistant from the head and neck if they are operating on the same side as the flap harvest; it also moves along with the operating table, thereby obviating the need to reposition it independently if the ablative surgeon requires repositioning of the operating table. When attached to the operating table, a hand surgery table can extend superior to the shoulder and even to the same level as the neck, displacing the ablative surgeon or assistant from the optimal operating position.[29]
Tourniquet Set-Up
A tourniquet may be placed in an unsterile or sterile fashion. If placed in an unsterile fashion, a cotton undercast is wrapped loosely around the biceps. A size-appropriate tourniquet is then fastened around the cotton undercast. If the tourniquet is placed sterilely, the entire arm is circumferentially prepped from the shoulder to the hand.
Sterility
The patient is prepped based on surgeon preference and patient allergies. If the tourniquet was placed in a non-sterile fashion, it is important to drape it to prevent it from contaminating the field. If the tourniquet is placed sterilely, the arm should be circumferentially prepped from the shoulder to the hand. The arm and the operating table extension where the flap is harvested and draped. Antibiotics are administered before skin incision. The antibiotic and dose are determined by surgeon preference.
Technique or Treatment
The procedure can be performed under tourniquet ischemia in an exsanguinated or unexsanguinated arm or without the tourniquet. Some surgeons prefer this procedure on an exsanguinated arm under a tourniquet set to 250 mmHg for no more than 2 hours. The arm can be exsanguinated with an Esmarch wrap before tourniquet inflation if desired.
The skin paddle is designed around the radial artery. The distal incision of the skin paddle is placed proximal to the head of the radius (typically, for a fasciocutaneous radial forearm free flap, the distal incision is placed in a transverse wrist crease, distal to the head of the radius). The skin paddle is placed on an island by cutting through the skin and subcutaneous fat around it to identify the fascia of the forearm muscles. Medially, the flexor carpi radialis and palmaris longus are identified. Subfascial or suprafascial dissection can be carried out just short of the lateral border of the flexor carpi radialis muscle belly. Laterally, the brachioradialis muscle is identified; the distal cephalic vein and the superficial branch of the radial nerve are also encountered. Incisions along the proximal edge of the skin island are also made down to the flexor carpi radialis and brachioradialis muscles; care should be taken during this step, as the cephalic vein is likely encountered again. Preservation of the vein may provide a secondary drainage system for the flap. The final incision around the skin paddle is on the distal forearm. The incision is made through the skin and subcutaneous fat. The distal pedicle is found amongst the deep fibrous band of tissue in the distal forearm.
A lazy-S incision is made from the proximal aspect of the skin paddle to the antecubital fossa through the skin and subcutaneous fat. The fascia of the brachioradialis and the flexor carpi radialis are identified. Medially, flaps are elevated over the flexor carpi radialis muscle fascia. Laterally, flaps are elevated over the brachioradialis muscle fascia. The superficial drainage system generally runs over the brachioradialis; it is dissected out and followed proximally where it can commonly be seen diving to join the deep venous system just distal to the antecubital fossa in the so-called "rat's nest" of venous anastomoses. The septum between the flexor carpi radialis and brachioradialis muscle bellies is opened to expose the radial artery and the venae comitantes that provide inflow and primary outflow to and from the flap, respectively. The vascular pedicle is then isolated by ligating its branches and tributaries along its length. As the skin island approaches, care is taken to preserve deep branching tributaries that may be periosteal feeding vessels to the radius.
At this point, the skin island of the flap can be elevated off the muscles of the forearm. If there is any concern at the start of the procedure of a non-viable distal extremity, an intraoperative Allen test can be performed by placing an Acland clamp on the radial artery at the distal wrist and releasing the tourniquet. This test demonstrates the conditions of ulnar-only artery flow to the hand. If there is a clinical suggestion of ischemia, the flap is aborted. Of course, this test can be done at any time during the procedure, based on the surgeon’s preference. Suppose the surgeon is otherwise confident about the hand’s ability to perfuse the ulnar artery alone. The procedure can be continued by ligating the distal venae comitantes and the radial artery. A silk suture is used to ligate the radial artery with a long tail placed on the flap side to facilitate observation of pulsations in the distal flap after the tourniquet is released and after microvascular anastomosis is completed. With the pedicle, the distal skin island is elevated off the brachioradialis and flexor carpi radialis tendons, taking care to maintain the integrity of the paratenons to prevent the tendons from adhering to the skin graft postoperatively.
Along the lateral aspect of the skin island, the distal cephalic vein is ligated. The superficial branch of the radial nerve is identified and preserved as much as possible. Some nerve branches may be seen diving into the flap and need to be sacrificed. The nerve is seen diving underneath the brachioradialis muscle along its proximal course. Dissection is then performed along the medial aspect of the brachioradialis muscle with the recruitment of the soft tissues of the lateral intermuscular septum. Paratenon should be preserved during this step to reduce the risk of postoperative tendon complications. The brachioradialis is laterally retracted, and the fibrofatty tissue deep to the muscle belly and tendon is recruited into the flap. It is within this fibrofatty tissue that periosteal feeding vessels are located. Care is taken not only to preserve this drape of fibrofatty tissue but also to preserve the deep course of the superficial branch of the radial nerve. The radius and the deep muscles of the forearm should be in view now. The pronator teres muscle defines the proximal limit of bone that can be harvested. Along the medial aspect of the radius, the flexor digitorum superficialis, flexor pollicis longus, and pronator quadratus are transected, and each muscle is divided close to the bone. The tourniquet is released. Hemostasis is obtained and attention is then turned to the osteotomies.
How the osteotomies are performed depends upon the surgeon's preference. The author prefers to perform right-angle cuts to remove a rectangular block of bone through the distal and proximal limits of the osteotomies, as opposed to a “canoe boat” or “keel-boat” which is often described. Care is taken to preserve the periosteum over the bone when exposing the bone for osteotomy. The length of the bone to be harvested is delineated. The limits of the bone harvest are the head of the radius distally and the insertion of the pronator teres muscle proximally. Roughly 50% of the height of the radius is identified by visual inspection and palpation with the arm pronated and supinated. A scalpel can be used to incise the periosteum and mark the planned osteotomies. Osteotomies can then be made with the saw along the incised periosteum. Care should be taken during the completion of the vertical osteotomies to avoid pass-cutting into the residual radius. Doing so can weaken the bone that remains after graft harvest. Once the osteotomies are complete, the flap can be elevated out of the forearm, pedicled by the vascular bundle feeding it.
The proximal venous and arterial anatomy is then defined before ligation and the start of flap ischemia time. The deep (primary) and superficial (secondary) venous systems often combine to create a single, large-caliber vein for anastomosis. The radial artery is followed distally to proximally, where 2 bifurcations can be observed. The more distal bifurcation is between the radial artery and the recurrent radial artery, the more proximal bifurcation is between the radial artery and the ulnar artery at the termination of the brachial artery. This point is the uppermost limit of where the radial artery can be taken. Injury to the proximal ulnar artery creates an elevated risk of distal ischemia. Taking the radial artery just distal to the branching point of the recurrent radial artery often provides ample length and vessel caliber for microvascular anastomosis. It also avoids the risk of injury to the ulnar artery. Once the flap is ready to be transferred, the donor vein and artery are ligated, and the flap becomes ischemic. The flap is then inset according to the reconstruction planned, and microvascular anastomosis is performed.
Prophylactic plating of the radius is strongly recommended because the partial thickness ostectomy significantly weakens the radius. Though the reconstructive surgeon may perform the plating of the forearm, many prefer to have an orthopedic surgeon plate the forearm if one is available.
For closure, a suction drain is placed in the proximal forearm. The lazy-S incision is closed in layers according to the surgeon's preference. The plate can be covered by advancing the remaining muscle bellies of the transected flexor digitorum superficialis and the flexor pollicis longus muscle to the brachioradialis tendon. A skin graft is harvested from the thigh and inset to the skin island defect. Negative pressure therapy or a bolster is placed to improve the chance of skin graft survival. The wrist is then wrapped and immobilized in a cast for 7 days.
Complications
The fasciocutaneous radial forearm free flap is generally a very reliable flap with a very high success rate, which is why it is a workhorse flap. The modification to preserve the lateral intermuscular septum and the periosteal feeding vessels and include a partial thickness segment of radial bone does not significantly affect the success rate of using this flap.
As with all microvascular procedures, flap failure at the microvascular level is the most concerning complication. Surgeon experience, operative technique, and vessel geometry are important factors that contribute to success or failure. Flap failure can be arterial or venous. Situations in which vessel geometry may lead to kinking, obstruction, or excessive tension should be avoided. Thoughtful flap inset is particularly important when mucosal incisions are being sealed to avoid the effects of a potential salivary fistula on the microvascular anastomosis. However, even in a smooth, well-scripted surgical procedure, many patient and patient care factors can contribute to a failed free flap intraoperatively and/or postoperatively. Identifying and avoiding those factors is key to reducing complications and length of hospitalization. Early recognition of flap failure may also salvage a compromised flap; otherwise, secondary or replacement reconstruction may be necessary. In a study by Mirzabeigi et al, they reviewed a series of 2260 microvascular flaps with a 3% take-back rate for delayed microvascular compromise and a 49% salvage rate.[30]
Regarding the harvested radial bone graft, fracture, malunion, nonunion, insufficient bone, and bony resorption are potential risks. Hardware complications, such as plate infection or extrusion, may also occur. Other recipient site complications include delayed healing, wound breakdown, and poor cosmesis. Wound healing problems may necessitate secondary procedures or reconstructions.
At the donor site, the most devastating complication with any radial forearm free flap is ischemia to the hand, which is rare, fortunately. There are several preoperative and intraoperative tests to help avoid this complication. Injury to the superficial branch of the radial nerve can result in the development of painful neuromas in the forearm. The skin paddle site is often closed with a skin graft, which can be cosmetically displeasing to the patient. Full-thickness skin grafting or augmenting the wound bed with a synthetic dermal regeneration matrix before placing a split-thickness skin graft may decrease the likelihood of aesthetic dissatisfaction. Skin graft failure is another potential complication, which may result from hematoma, denuded tendons, poor wound healing, and/or infection. Delayed skin graft failure may present in conjunction with tendon exposure. Aggressive recruitment of tissue into the flap during harvest, particularly in preserving the perforators to the radius, may injure or denude the brachioradialis tendon or its paratenon, thereby increasing the risk of tendon exposure or injury.
Other complications more specific to the osteocutaneous radial forearm result from loss of radial bone strength and myotomies of the flexor digitorum superficialis, flexor pollicis longus, and pronator muscles. Biomechanical studies confirm the significant loss of strength accompanies the loss of radial bone thickness. The risk of pathologic fracture of the radius is higher after radial ostectomy. Prophylactic plating is recommended to reduce the risk of fracture. Plate infection and/or exposure is possible in the donor's forearm but is fortunately quite rare.[22] Very little objective or quality-of-life data have been published concerning the functional effects of wrist muscle myotomy after OCRFFF. A study in 1994 assessed a small series of consecutive OCRFFF patients for functional deficits; it found a high incidence of decreased pronation, flexion, and extension.[31] Key pinch strength on the operated forearm was 74% of the non-operated hand. Another study in 2012 also sought to examine the overall effect of the donor site morbidity from this procedure. The investigators concluded that there was minimal objective donor site loss of function. They also stated that mild wrist weakness and stiffness are common but do not significantly impact daily activities.[21]
Few studies compare complications of the OCRFFF to other osteocutaneous reconstructive options. A retrospective study of 168 patients examined differences between the osteocutaneous radial forearm and the osteocutaneous fibular flap. The OCRFFF was more commonly used in older patients (63.7 versus 59 years of age). Flap failure rates were similar (~3-4%). In their series, the donor site complication rate was higher in the fibular-free flap group (4.3%) versus the OCRFFF group (0%).[20] Another group in 2018 performed a comprehensive literature search to assess morbidities comparing the OCRFFF, fibular free flap, scapular free flap, and iliac crest free flap. They concluded that the radial forearm and fibular osteocutaneous flaps had the highest rates of delayed healing, nearly double that of the scapular flap and quadruple that of the iliac crest. They reported that the OCRFFF had the highest rates of chronic pain (16.7%) and dissatisfaction with scar appearance (33%). They, too, concluded that the OCRFFF placed no significant limitations on daily activities but advocated the scapular flap over the fibular and osteocutaneous radial forearm flaps.[32] The OCRFFF may not always be the ideal or first choice for reconstruction; however, it is an excellent option for reconstructive surgeons to have in their armamentaria.
Clinical Significance
The radial forearm free flap is one of the most commonly utilized reconstructive modalities in the head and neck. The ability to harvest a partial thickness segment of radial bone for an osteocutaneous radial forearm free flap provides a powerful, versatile option in the armamentarium of the reconstructive surgeon. It is an alternative to other osseous-free flaps, namely, the fibular, scapular, and iliac crest-free flaps. Understanding the advantages, disadvantages, and complications associated with each reconstruction can help the surgeon and patient set realistic expectations and optimize the surgery outcomes.
Enhancing Healthcare Team Outcomes
Teamwork results in the best outcomes. Perhaps most important to the survival of the flap in the early postoperative period is the experience of the critical care nurses taking care of the patient and performing regular evaluations of the flap's viability. Experienced clinicians who are supported by a responsive surgical call team are more likely to recognize early signs of vascular insufficiency in the flap, generally venous congestion, and are therefore more likely to appropriately request an evaluation by a microvascular surgeon, who can then salvage the flap in a timely fashion, if necessary. A delay of more than 6-8 hours between cessation of adequate blood flow to the flap and restoration of perfusion carries with it a very high risk of flap death, which then often requires that the patient undergo a secondary reconstructive procedure.[33]
Media
(Click Video to Play)
Modified Allen Test. The modified Allen test evaluates whether the ulnar artery can adequately supply blood to the hand if the radial artery is ligated, such as during a radial forearm flap harvest.
Contributed by MH Hohman, MD, FACS
References
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Level 3 (low-level) evidenceSoutar DS, Scheker LR, Tanner NS, McGregor IA. The radial forearm flap: a versatile method for intra-oral reconstruction. British journal of plastic surgery. 1983 Jan:36(1):1-8 [PubMed PMID: 6821714]
Vaughan ED. The radial forearm free flap in orofacial reconstruction. Personal experience in 120 consecutive cases. Journal of cranio-maxillo-facial surgery : official publication of the European Association for Cranio-Maxillo-Facial Surgery. 1990 Jan:18(1):2-7 [PubMed PMID: 2303549]
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Level 3 (low-level) evidenceSwanson E, Boyd JB, Manktelow RT. The radial forearm flap: reconstructive applications and donor-site defects in 35 consecutive patients. Plastic and reconstructive surgery. 1990 Feb:85(2):258-66 [PubMed PMID: 2300632]
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Swanson E, Boyd JB, Mulholland RS. The radial forearm flap: a biomechanical study of the osteotomized radius. Plastic and reconstructive surgery. 1990 Feb:85(2):267-72 [PubMed PMID: 2300633]
Meland NB, Maki S, Chao EY, Rademaker B. The radial forearm flap: a biomechanical study of donor-site morbidity utilizing sheep tibia. Plastic and reconstructive surgery. 1992 Nov:90(5):763-73 [PubMed PMID: 1410028]
Level 3 (low-level) evidenceBardsley AF, Soutar DS, Elliot D, Batchelor AG. Reducing morbidity in the radial forearm flap donor site. Plastic and reconstructive surgery. 1990 Aug:86(2):287-92; discussion 293-4 [PubMed PMID: 2367577]
Villaret DB, Futran NA. The indications and outcomes in the use of osteocutaneous radial forearm free flap. Head & neck. 2003 Jun:25(6):475-81 [PubMed PMID: 12784239]
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Level 2 (mid-level) evidenceArganbright JM, Tsue TT, Girod DA, Militsakh ON, Sykes KJ, Markey J, Shnayder Y. Outcomes of the osteocutaneous radial forearm free flap for mandibular reconstruction. JAMA otolaryngology-- head & neck surgery. 2013 Feb:139(2):168-72. doi: 10.1001/jamaoto.2013.1615. Epub [PubMed PMID: 23429948]
Level 2 (mid-level) evidenceClements JR, Mierisch C, Bravo CJ. Management of combined soft tissue and osseous defect of the midfoot with a free osteocutaneous radial forearm flap: a case report. The Journal of foot and ankle surgery : official publication of the American College of Foot and Ankle Surgeons. 2012 Jan-Feb:51(1):118-22. doi: 10.1053/j.jfas.2011.10.022. Epub 2011 Nov 13 [PubMed PMID: 22083066]
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Kim SK, Kim TH, Yang JI, Kim MH, Kim MS, Lee KC. The etiology and treatment of the softened phallus after the radial forearm osteocutaneous free flap phalloplasty. Archives of plastic surgery. 2012 Jul:39(4):390-6. doi: 10.5999/aps.2012.39.4.390. Epub 2012 Jul 13 [PubMed PMID: 22872844]
Salgado CJ, Fein LA, Chim J, Medina CA, Demaso S, Gomez C. Prelamination of Neourethra with Uterine Mucosa in Radial Forearm Osteocutaneous Free Flap Phalloplasty in the Female-to-Male Transgender Patient. Case reports in urology. 2016:2016():8742531. doi: 10.1155/2016/8742531. Epub 2016 Mar 16 [PubMed PMID: 27069708]
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Fujioka M, Hayashida K, Murakami C, Koga Y. Reconstruction of total nasal defect including skin, bone, and lining, using a single free radial forearm osteocutaneous perforator flap. Plastic and reconstructive surgery. 2012 May:129(5):854e-857e. doi: 10.1097/PRS.0b013e31824a9e7f. Epub [PubMed PMID: 22544128]
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Level 2 (mid-level) evidenceSmith AA, Bowen CV, Rabczak T, Boyd JB. Donor site deficit of the osteocutaneous radial forearm flap. Annals of plastic surgery. 1994 Apr:32(4):372-6 [PubMed PMID: 8210155]
Kearns M, Ermogenous P, Myers S, Ghanem AM. Osteocutaneous flaps for head and neck reconstruction: A focused evaluation of donor site morbidity and patient reported outcome measures in different reconstruction options. Archives of plastic surgery. 2018 Nov:45(6):495-503. doi: 10.5999/aps.2017.01592. Epub 2018 Nov 15 [PubMed PMID: 30466228]
Boissiere F, Gandolfi S, Riot S, Kerfant N, Jenzeri A, Hendriks S, Grolleau JL, Khechimi M, Herlin C, Chaput B. Flap Venous Congestion and Salvage Techniques: A Systematic Literature Review. Plastic and reconstructive surgery. Global open. 2021 Jan:9(1):e3327. doi: 10.1097/GOX.0000000000003327. Epub 2021 Jan 22 [PubMed PMID: 33564571]
Level 1 (high-level) evidence