Superficial dorsal artery of the forearm: case report and review of the literature

Although abnormalities of vascular anatomy in the forearm are common, variations of the radial and ulnar arteries are rare. Nevertheless, arterial variants in the forearm may present clinically with neurovascular signs or symptoms. Even when anomalous arteries are not apparent, they may complicate surgery of the forearm and hand, as well as reconstructive surgery that involves the harvest of radial or ulnar artery-based forearm free flaps. For example, the superficial ulnar artery has an incidence of 2.7% and has been well described as a "hidden trap" in the harvest of radial forearm flaps. We present a case report of a variant of the radial artery-the superficial dorsal artery of the forearm. This artery has an estimated incidence of 0.75% and is associated with either an absent or small-caliber radial artery. We believe this is the first report of such an artery presenting to clinical attention, as well as the first imaging of this structure with magnetic resonance angiography. The embryology of this structure and its clinical implications to the hand surgeon, peripheral vascular surgeon, and reconstructive microsurgeon, are also discussed.     

Superficial ulnar artery: curse or blessing in harvesting fasciocutaneous forearm flaps

BACKGROUND: Superficial ulnar artery is a well-known vascular anomaly that may cause special risks because of possible impairment of the vessel by mistake during harvesting fasciocutaneous forearm flaps. METHODS: The charts of patients who had undergone forearm flap transfer were reviewed for vascular anomalies. When a superficial ulnar artery was present, a superficial ulnar artery flap was raised and arteriography was performed postoperatively to figure out the vascular pattern in the contralateral arm. RESULTS: Four superficial ulnar arteries were found during dissection of ulnar forearm flaps (n = 107). We were unable to identify any superficial ulnar artery when preparing the radial pendant (n = 27), and we did not notice any impairment of such an artery. The four superficial ulnar artery flaps healed uneventfully. Postoperative arteriography revealed a bilateral vascular anomaly in one of the four cases. CONCLUSION: The superficial ulnar artery is a calculable anatomic variation as long as its possible presence is considered during flap harvesting. In these cases, the use of the superficial ulnar artery flap was found to be an easy and safe alternative.     

Superficial upper limb vasculature and its surgical implications

Any kind of anatomical variation whether encountered during cadaveric dissections or routine clinical or surgical procedures needs to be reported and taken into account. This can be quite helpful in planning surgeries accordingly and avoid disastrous complications. During routine cadaveric dissection, authors found a superficial course of arteries of the arm as well as the forearm, unilaterally in one cadaver. In this case, there were two brachial arteries – superficial and deep. Superficial brachial artery terminated into superficial radial and superficial ulnar artery. Deep brachial artery was trifurcated into common interosseous, medial and lateral artery branches. Authors have also discussed the developmental anomaly, which could have led to the observed morphological variation. Superficial vessels can provide large size pedicles for raising flaps for local reconstructive surgeries in the region of axilla, elbow, wrist or hand, or other regions.KEY WORDS: Artery, brachial, radial, superficial, ulnar     

Absence of the brachial artery: report of a rare human variation and review of upper extremity arterial anomalies

Variations in the arterial anatomy of the upper extremities, although uncommon, occur in up to one in five patients. Most of these variants occur in either the radial or ulnar artery; brachial artery variations are less common. The case we report is a rare anomaly consisting of brachial artery agenesis or regression. The brachial artery was absent from its origin but reconstituted as a normal-appearing vessel 3 cm above the antecubital fossa. The profunda brachii artery and the superior and inferior ulnar collateral arteries were also absent in this patient. The axillary artery served as the main collateral to the forearm. This constellation of anomalies has not been previously described or explained by developmental models in humans and other primates. We speculate that failure of development or arrest of specific vascular anlage in the upper extremity occurs at particular embryological stages because of unknown factors.     

Upper extremity salvage with a flow-through free flap

In complex extremity injuries, which include composite tissue lost with devascularization caused by segmental vascular damage, simultaneous coverage of the defects with revascularizations should be required. One-stage reconstruction of both soft tissue coverage and vascular damage can be performed by a flow-through-type free flap. In this series, 5 patients between 13 and 36 years of age with wide composite tissue defects in the cubital region and segmental defects in brachial arteries were operated at our clinic between 1996 and 2003. With the aim of reconstructing the wide tissue defects in the cubital region as well as that of the brachial artery, a radial arterial flow-through flap was applied. The radial artery of the flow-through flap was anastomosed to the proximal ends of the brachial and ulnar arteries in an end-to-end fashion. In 4 of the patients, the radial arterial flow-through flap was prepared from the distal aspect of the wounded forearm and in 1 patient from the contralateral forearm. In the postoperative period, no complications related to the anastomosis were encountered in the flap with all anastomoses found to be patent, and distal circulation was restored. The radial arterial flow-through flap is very useful in the clinical field of major trauma of the cubital region with brachial artery damage with numerous advantages that include the opportunity to work in one single surgical area, shorter dissection times resulting from simple and fixed anatomy, perfect color and tissue adaptation, and the suitability of the vessel caliber and length.     

A study of variable origins of arteries in arm

A series of anomalous arterial supply of the arm and shoulder is presented. In these cases, the deep brachial artery arose from a common trunk with posterior circumflex humeral artery. In one case, the superior ulnar collateral artery and deep brachial artery originated from the posterior circumflex humeral artery. The common trunk or posterior circumflex humeral artery arose from the brachial artery at the level of the lower border of the teres major (at the origin of the brachial artery). A possible ontogenetic explanation is provided for this situation. Awareness of the variations of arteries of the arm or shoulder is important for angiographers and the surgeon who operates in this region. Preliminary part of this study was presented at the 1st Joint Meeting of EACA (European Association of Clinical Anatomy), AACA (American Association of Clinical Anatomists), Graz, Austria, 7–11 July, 2003.     

Anatomic study of distally based pedicle compound flaps with nutrient vessels of the cutaneous nerves and superficial veins of the forearm

The purpose of this study was to describe the anatomic basis for a distally based neurovenovascular pedicle compound flap, with nutrient vessels of the cutaneous nerves and superficial veins of the forearm. In this study, the origins, branches, and anastomoses of nutrient vessels of the cutaneous nerves and superficial veins of the forearm and their relationships with the blood supply of adjacent muscle, bone, and skin were assessed in 96 adult cadavers by perfusion of red gelatin into the superior limb arteries. The results showed that the nutrient vessels of cutaneous nerves and superficial veins of the forearm were found to have multiple origins, consisting of six longitudinal vascular plexuses and one transverse vascular plexus of the forearm, as follows: 1) the anterior-lateral vascular plexus from cutaneous branches of the radial artery; 2) the anterior-medialis vascular plexus from cutaneous branches of the ulnar artery; 3) the dorso-lateral vascular plexus from radial osteal and cutaneous branches; 4) the dorso-medialis vascular plexus from ulnar osteal and cutaneous branches; 5) the radial vascular plexus from osteal and cutaneous branches of the radial artery, cutaneous branches of the radial artery in the upper wrist, recurrent branches of the styloid process of the radius, and the radialis vascular plexus of cutaneous branches of the tabatière anatomique (anatomical snuffbox); and 6) the ulnar lateral vascular plexus from cutaneous branches of the ulnar artery in the upper wrist and osteal and cutaneous branches. The transverse vascular plexus is composed of dorsal branches of the ulnar and radial arteries. These perforating branches give fascial branches, cutaneous branches, periosteal branches, and nutrient vessels of cutaneous nerves and superficial veins. These results suggest that nutrient vessels of the cutaneous nerves and superficial veins of the forearm have the same origins as those of the nutrient vessels of adjacent muscles, bones, and skin of the forearm, which can be designated as five types of distally based pedicle flaps with nutrient vessels of cutaneous nerves and superficial veins of the forearm, whose rotation point is at the wrist joint. This flap can be applied to repair tissues of distal parts of the hand.     

应用数字减影血管造影术指导皮瓣选择修复严重手外伤创面

目的本文探讨数字减影血管造影术(Digital subtraction angiography,DSA)在严重手外伤治疗中,对皮瓣选择的指导作用。方法回顾性分析我科治疗的6例手外伤患者,创面均有肌腱和(或)骨外露,所有患者均行DSA检查,明确前臂和手的血供情况,包括桡动脉、尺动脉的走行及其穿支动脉、掌深弓掌浅弓的存在与否等。根据造影结果,综合评价血管损伤情况和邻近的软组织条件,并据此选择逆行前臂岛状皮瓣或远位游离皮瓣修复创面。结果 4例患者前臂及手掌部主干血管无损伤,选择逆行前臂轴型皮瓣修复。2例患者因前臂桡动脉断裂、掌深弓掌浅弓完整性缺失而选择游离轴型皮瓣修复创面,术后皮瓣均存活。结论 DSA造影可以清晰显示患侧前臂和手的血管网,发现可能存在的血管损伤,能有效地指导皮瓣的选择,提高皮瓣选择的合理性和皮瓣移植的成功率。     

The ulnar nerve as vascularized nerve transplant. Part I: Anatomy: arterial vascular supply

The ulnar nerve is supplied basically by the arteries accompanying it in its various locations: in the axillary section, by a branch of the lateral thoracic artery or directly by the axillary artery; in the upper arm, by branches originating from the collateral ulnar superior artery; in the supracondylar section and in the region of the groove for the ulnar nerve, by branches originating from the anastomosis of the collateral arteries and the posterior branch of the recurrent ulnar artery; and in the forearm, by branches of the recurrent ulnar artery and the ulnar artery. Venous return is by the venae comitantes. Since the ulnar nerve possesses a good arterial supply, it may be used with different techniques as a vascularized nerve transplant in traumatic lesions of the brachial plexus, to repair more important missing nerve paths.     

The free ulnar forearm flap

Many flaps have been described based on the septocutaneous perforators; these have many advantages for the coverage of soft tissue defects. The ulnar forearm flap described by Lovie is a septocutaneous flap based on the septocutaneous perforators of the ulnar artery. We report the use of this flap in 2 patients who required soft tissue coverage. The ulnar forearm flap has the advantages of thin and pliable skin, constant and large pedicle, and the technical possibility of combination with the muscles, sensory or motor nerve, and ulna. Comparing it with the radial forearm flap, there is no possibility of exposure of flexor tendons, which usually results in the good take of skin grafts. After skin grafting, the donor scar is unnoticeable because of its position on the forearm. This flap is for the coverage of thin defects that require mobility, such as in the extremities or the intraoral region. It also could be used for the coverage of hand or arm defects as a distally or proximally based island flap, respectively.     

Analysis of flow changes in forearm arteries after raising the radial forearm flap: a prospective study using colour duplex imaging.

The purpose of this study is to assess the changes in flow patterns of forearm arteries produced by excision of the radial artery when harvesting the radial forearm flap, in order to clarify its vascular morbidity rationally. Eleven patients with elective surgery using the radial flap were included in this investigation. A prospective study was designed using colour duplex imaging for quantitative flow measurement in two stages: a few days before the operation, a first colour duplex scanning examination was done recording flow velocity and vessel section area from the radial, ulnar, posterior interosseous and anterior interosseous arteries around the wrist. Volumetric parameters and relative blood flow percentages were calculated and compared to those obtained from a second similar vascular investigation accomplished in the same limb 4-5 months after the operation. Statistical analysis was done using the Wilcoxon matched pairs test. After raising the radial forearm flap there was a trend for increased overall forearm flow (from 162 to 215 ml/min, P = 0.09 N.S.), the ulnar (P = 0.04), the posterior interosseous (P = 0.004) and the anterior interosseous (P = 0.003) arteries being responsible for this tendency. The anterior interosseous artery showed the greatest increase in blood (from 8.2 to 67.7 ml/min), reaching a relative flow percentage (33%) close to that of the radial artery before its excision (39%). Results of this study indicate that another 'major vascular axis' based on the anterior interosseous artery develops after sacrificing the radial artery and that global arterial inflow to the hand is not impaired.     

A rare variant of the radial artery: clinical considerations in raising a radial forearm flap.

A rare vascular anomaly of the radial artery encountered during elevation of a radial forearm free flap is reported in this paper. We discovered a superficial radial artery which bifurcated from the deep radial artery 4 cm below the antecubital fossa. The blood supply to the proximal radial forearm flap was thought to be from the superficial radial artery, and to the distal forearm flap from both arteries. Ascertaining the course of the radial artery pre- and intraoperatively and careful dissection of the artery are essential to minimise problems of flap transfer.     

Anomalies of forearm vascular anatomy encountered during elevation of the radial forearm flap

Background. The radial forearm flap has gained considerable popularity over the past 10 years. With the increasing number of forearm flaps being used in head and neck reconstruction, it is likely that anomalous forearm vascular anatomy will be encountered by more head and neck surgeons performing this procedure. Methods. We reviewed our experience with 52 forearm flaps; four different anomalies of forearm vascular anatomy were encountered in four patients. In this article we present each of our cases and discuss the incidence, preoperative diagnosis, and recommended management of these and the more common forearm vascular anomalies. Results. The anomalies encountered in our series include: one case of distal takeoff of the radial artery deep to the pronator teres muscle, two cases of a superficial dorsal antebrachial artery, one case of bilateral hypoplastic ulnar arteries, and one case of high takeoff of the radial artery. Conclusions. There are a number of anomalies of forearm vascular anatomy of clinical significance to the surgeon performing these procedures. Most of these anomalies can be identified with a careful preoperative examination. Surgeons performing this procedure should be familiar not only with the normal vascular anatomy of the forearm flap, but also with the more common anatomic variants. Failure to recognize or appropriately manage these anomalies of forearm vascular anatomy may result in a compromised surgical outcome. © 1995 Jons Wiley & Sons, Inc.     

The radial artery is larger than the ulnar

BACKGROUND: The radial artery is presently widely used as a bypass graft for coronary artery reconstruction. However, the traditional opinion that the ulnar artery is the larger forearm artery has been questioned. METHODS: The internal diameters of the radial and ulnar arteries were measured at the wrist in postmortem angiograms of 24 cadavers. Differences in mean values of variables between ulnar and radial arteries were analyzed using the Wilcoxon test. RESULTS: The mean diameter of the radial artery was 28% larger than that of the ulnar artery in the right arm (p < 0.001) and 26% larger in the left arm (p < 0.001). In the right arm the radial artery was dominant in 20 of 24 cadavers (83%), the ulnar artery in 3 of 24 (13%), and the arteries were equal in 1 of 24 (4%). In the left arm the figures were 17 of 24 cadavers (71%), 3 of 24 (13%), and 4 of 24 (17%), respectively. CONCLUSIONS: In view of the present investigation the radial artery should be considered the larger forearm artery of the hand in most patients.     

Fascial flaps based on perforators for reconstruction of defects in the distal forearm.

Twenty fascial flaps were used in the reconstruction of defects in the distal forearm, wrist and hand in 18 patients over a 2-year period. In 16 patients the fascial flaps were based on a single fascial feeding vessel or 'perforator' arising from the anterior interosseous artery and/or ulnar artery when the radial artery had been used as the donor vessel in free flap reconstruction elsewhere in the body. There was no loss of any fascial flap in the study. The use of fascial flaps based on fascial feeders of the anterior interosseous and ulnar arteries extends the range of fascial flaps that can be raised in the forearm for reconstruction of defects in the distal forearm, wrist and hand.     

Hand blood supply in radial forearm flap donor extremities: a qualitative analysis using doppler examination

This retrospective study evaluated the contribution of the forearm arteries to the blood supply of the hand after radial forearm flap surgery. Doppler ultrasound examinations of the radial, ulnar, anterior interosseous and posterior interosseous arteries were performed in the distal forearm using a continuous emission directional Doppler and a modified Allen test. Twenty-seven patients were included in this investigation which demonstrated a significant contribution of the anterior interosseous artery to hand vascularity after radial forearm flap surgery.     

High bifurcation of brachial artery with acute arterial insufficiency: a case report

The upper extremity arterial system shows a large number of variations in the adult human body. Most of these variations occur in either the radial or ulnar artery; brachial artery variations are less common. Because the upper extremity is a frequent site of injury and various surgical and invasive procedures are performed in this region, it is of utmost importance to be aware of arterial variations. We report a case of a high bifurcation of the brachial artery presenting with acute ischemia secondary to an embolic event. The anomaly was identified, and the ischemia was successfully resolved with embolectomy.     

Harvest of the radial artery for coronary artery surgery preserves maximal blood flow of the forearm

Background

Use of the radial artery as a conduit for coronary artery surgery has increased dramatically. It has been assumed that blood flow to the forearm will not be compromised by its removal.

Methods

Sixteen patients who had the left radial artery harvested for coronary surgery at least 3 months earlier were studied. The right radial artery was not harvested. The radial, ulnar, and brachial artery diameters and flows were measured using pulsed wave Doppler with a 15-MHz linear array transducer. Measurements were performed at rest, with the right radial artery compressed, and after ischemia with forearm exercise.

Results

At rest, the (mean ± SE) diameter of the left ulnar artery was consistently greater than the right (2.4 ± 0.09 versus 2.1 ± 0.09 mm, p = 0.001) as was flow (74 ± 9.9 versus 48 ± 8.5 mL/min, p = 0.005). There was no difference between diameters or flows in the brachial arteries. After compression of the radial artery, flow increased in the right ulnar artery from 39 ± 8.0 to 72 ± 17.6 mL/min (p = 0.019) without an increase in ulnar artery size and was not different from the left ulnar artery flow at rest (p = 0.440). After ischemic forearm exercise, flow increased in the two brachial arteries almost equally (left, 348 ± 50; right, 371 ± 63 mL/min).

Conclusions

Blood flow to the forearm and hand is not compromised by harvest of the radial artery.