The blood supply of the reverse temporalis muscle flap: anatomic study and clinical implications

Although the reverse temporalis muscle flap has been used clinically, the exact vascular connection between the superficial and deep temporal vessels has not been clearly defined. The purpose of this study was to investigate the vascular territory of the reverse temporalis muscle supplied by the superficial temporal vessels. Six cadaver heads were studied using a colored lead oxide injection through the superficial temporal artery. The specimens were examined macroscopically and radiographically. The reverse temporalis muscle flap was then applied to a clinical case presenting with traumatic anterior skull base defect communicating with the nasal cavity. The cadaver specimens demonstrated that the superficial temporal artery formed an average 1.3 +/- 0.2 cm in width of dense vascular zone, which was located within 1.8 cm below the superior temporal line. The dense vascular network further perfused the anterior and posterior deep temporal arteries and the muscular branch of the middle temporal artery to supply the temporalis muscle. The mean perfused area of the temporalis muscle was 83 percent, ranging from 79 to 89 percent, in five cadaver heads. One cadaver revealed only 55 percent of perfused area in the absence of the muscular branch of the middle temporal artery. The consistent area without perfusion was located in the distal third of the posterior portion of the reverse temporalis muscle. In clinical cases, the reverse temporalis muscle flap was used successfully to obliterate the anterior skull base defect without evidence of muscle flap necrosis. The exact blood supply to the distal third of the posterior portion of the reverse temporalis muscle flap needs to be investigated further in vivo. Particular attention was paid to the inclusion of the muscular branch of the middle temporal artery in this flap to augment the blood supply to the temporalis muscle.     

Late bleeding after rhytidectomy from injury to the superficial temporal vessels

Five healthy, normotensive women, whose mean age was 49.8 years, developed expanding hematomas between 8 and 10 days (average 9 days) after rhytidectomy. In each patient, the bleeding vessel could be identified: In two, it was the parietal branch of the superficial temporal artery; in two, it was the parietal branch of the superficial temporal vein; and in one, it was the superficial temporal artery immediately before its branching. Contributing factors may have been sudden physical exertion in four of the five patients and in another salicylate ingestion. Several measures can help avoid late bleeding from the superficial temporal vessels or their branches; not using a too potent vasoconstrictive agent (epinephrine) in the local anesthetic so that the vessels will be easier to visualize; not injecting the local anesthetic too deeply or incising to deeply; dividing and ligating the superficial temporal vessel and its major branches if injured; using bipolar coagulation on small branches; and instructing patients repeatedly not to engage in strenuous activity or to ingest salicylates for at least 2 weeks after operation.     

Arterial supply of the anterior ear.

Twenty cadaver auricles were injected with a latex solution to define the arterial supply of the anteroauricular surface. Two arterial networks exist, the network of the triangular fossa-scapha and the network of the concha. Both eventually communicate on the anthelix. The triangular fossa-scapha network originates from one subbranch of the upper auricular branch of the superficial temporal artery and from branches of the posterior auricular artery that come through the earlobe and triangular fossa and over the helical margin. The conchal network is provided by two to four perforators that come from the posterior auricular artery, piercing the conchal floor. Auricular branches of the superficial temporal artery in the preauricular region and their communications with the posterior auricular artery also were confirmed. We believe that a greater understanding of the detailed arterial anatomy in this area allows one to develop safely a variety of surgical techniques for reconstruction of the ear.     

Venous drainage architecture of the temporal and parietal regions: anatomy of the superficial temporal artery and vein

Anatomy of the superficial temporal artery and vein was analyzed with arteriograms, venograms, and arteriovenograms of fresh cadavers that had been injected with contrast medium. The superficial temporal artery always divided into two major branches: the frontal and parietal branches. However, the superficial temporal vein divided into one, two, or three major branches. The distribution area of the major branches of the superficial temporal vein was larger than that of major branches of the superficial temporal artery, and arteriovenograms clearly demonstrated that, except for its proximal portion, the superficial temporal vein was independent of the superficial temporal artery. The frontal and parietal branches of the superficial temporal artery had thin venae comitantes that originated from the proximal portion of the superficial temporal vein, and the venae comitantes gave off branches toward the skin and the underlying soft tissue. Branches to the skin anastomosed with a superficial venous network in the skin layer, which was formed by ramifications of the superficial temporal vein. The venous architecture of the temporal and parietal regions consisted of cutaneous veins and venae comitantes and was basically similar to that of the forearm and scapular region.     

Direct branch of external carotid: a masseteric artery

An additional branch of the right external carotid in the form of an unusual direct artery to m. masseter is described. It arose as a terminal branch along with the maxillary and superficial temporal arteries, ran in the substance of the parotid gland to supply the muscle on its lateral aspect. The pertinent anatomical literature is reviewed.     

The arteria radialis superficialis. An unusual variation of the arteria radialis of man and its phylogenetic significance

During the clinical investigation of 570 soldiers of the German army, we were not able to feel the pulse in 5 cases at the typical place of the radial pulse in the distal part of the forearm. In these 5 cases we were able to find a subcutaneous artery which coursed superficial to the anatomical snuffbox and crossed superficial to the tendon of the extensor pollicis longus muscle. This superficial radial artery enters the deep aspect of the palm between the first and the second metacarpale bones. In three cases we found a bilateral occurrence of this artery, the other variations were observed unilaterally, two on the right side and one on the left side of the forearm. In the family of two patients other members were found who had the same variation of the radial artery. In one of the cases an arteriography of the vessels was made to find the exact anatomical course of the observed variation. We compared our results with the literature on this variation of the radial artery and found agreement on the following course for this vessel. The radial artery divides in the distal fourth of the forearm (5-7 cm proximal to the wrist joint) into two branches. The dorsal branch courses subcutaneously over the tendon of the brachioradialis muscle and runs over the tendon of the extensor pollicis longus muscle to enter the deep aspect of the palm in the first metacarpal space. This dorsal branch courses parallel to the superficial branch of the radial nerve. The palmar branch can be regarded as the 'normal' radial artery, which continues along the medial border of the brachioradialis muscle and courses deep under the tendons of the dorsal muscles of the thumb. The rare appearance (frequency approximately 1%) of a superficial radial artery in man has probably some phylogenetic importance. This is proven by studies on the comparative anatomy of mammals. This variation of the radial artery seems to be homologous to the superficial radial artery which is described in many lower mammals. In human embryos a superficial radial artery is found as well which courses parallel to the superficial branch of the radial nerve and ends on the dorsal side of the hand. Taking all the anatomical and embryological facts into consideration we propose to name this variation of the radial artery the 'arteria radialis superficialis'.     

Surgical anatomy and blood supply of the fascial layers of the temporal region

In 15 fresh cadavers (30 sides), we studied the two layers of fascia in the temporal region, with particular regard to their blood supply and to their usefulness--together or separately--as microvascular free-tissue autografts. The superficial temporal fascia (temporoparietal fascia, epicranial aponeurosis) lies immediately deep to the hair follicles. It is part of the subcutaneous musculoaponeurotic system and is continuous in all directions with other structures belonging to that layer--including the galea above and the SMAS layer of the face below. The deep temporal fascia (temporalis fascia, investing fascia of temporalis) is separated from the superficial fascia by an avascular plane of loose areolar tissue. It completely invests the superficial aspect of the temporalis muscle down to (but not beyond) the zygomatic arch. It is firmly attached to periosteum all around the margin of the muscles. Below it is attached to the upper border of the zygomatic arch. We found the deep temporal fascia to be supplied solely by the middle temporal artery, a constant branch of the superficial temporal. The middle temporal artery arises 1 to 3 cm below the upper border of the zygomatic arch, runs always superficial to the arch, and enters the deep temporal fascia immediately above that layer's attachment to the zygomatic arch. If the middle temporal vessels are protected, the two layers of temporal fascia can be raised together as a fully vascularized tissue island. This island can be fashioned as a bilobed or a double-layered flap, depending on the manner of dissection. The potential surgical usefulness of these findings is discussed.     

A case of sideburn reconstruction using a temporoparieto-occipital island flap.

A preliminary case is reported in which a large temporal bald scar including the sideburn was successfully reconstructed using a temporoparieto-occipital island flap in combination with a tissue expander. This flap is considered to be a kind of reverse-flow island flap of the occipital artery by means of the fine vascular connections with the temporal branch of the superficial temporal artery. This new method is potentially a good solution for sideburn reconstruction.     

Anatomy of the frontal branch of the facial nerve: the significance of the temporal fat pad

The anatomy of the temporal region, with reference to the frontal branch of the facial nerve, was examined in 12 fresh cadaver dissections. In all dissections, the frontal branch traveled in a constant plane along the undersurface of the temporoparietal fascia and was quite superficial as it crossed the zygomatic arch. The deep temporal fascia and superficial temporal fat pad are anatomically important structures which adjoin the periosteum of the zygomatic arch and lie deep to the frontal nerve. Based on these relationships, a safe method of dissection within the temporal region is formulated.     

A newly defined conchal floor arterial flap for auricular reconstruction

A conchal floor composite flap pedicled by skin of the helical crus has been well described in the literature. Here the flap is elevated based on the supply by an upper auricular branch of the superficial temporal artery. In this article, a newly defined conchal floor arterial flap is proposed. The flap is based on the main stem of the posterior auricular artery and its venae comitantes. Two types of conchal floor arterial flaps were elevated: a proximally based chondral arterial flap and a distally based chondrocutaneous arterial flap. The proximally based flap was used for earlobe reconstruction, whereas the distally based flap was useful in the reconstruction of the upper auricle. Nine congenital auricular malformations were successfully corrected with this newly defined conchal floor flap procedure. This type of flap is easier to elevate, more reliable, and more versatile than the one currently in use.     

Abdominal part artery of axillary artery: proposed term for the artery supplying the abdominal part of the musculus pectoralis major.

In 1976, the authors reported that the abdominal part artery (Pab) supplying the abdominal part of the pectoralis major muscle usually originates from the axillary artery (Ax). The findings in the present study show that the type of origin of this artery most frequently encountered is type 2-a (44.0%) in which the Pab, as an independent branch (type a), branches out of the second part of the Ax (type 2). The second and third most frequently encountered types are type 2-b (17.0%), where the Pab has a common trunk with the thoracoacromial artery, and type 2-c (10.0%), where it has a common trunk with the lateral thoracic artery. By classification according to the supplying areas, 67% was type I-B, supplying the lower part of the pectoralis minor muscle and the abdominal part of the muscle. In 5%, the branch as type I-A courses down to the sternocostal part. In most cases (types A and B in 91%), this artery originates from the Ax proximal to the ansa mediana of the brachial plexus; however, in 4% providing the superficial brachial artery, the Pab branches out from the superficial brachial artery. Based on those findings, the authors would propose that the artery be named the arteria partis abdominalis or Pab.     

Secondary expansion of a replanted scalp salvaged by an intrinsic arteriovenous shunt.

1. Although scalping injuries reported in most large series rarely involve young children, partial scalp replantation, even in a 2-year-old boy after a dog-bite avulsion, should also be warranted. However, technical difficulties because of the diminutive vasculature can be expected. 2. Unconventional methods for reestablishing inflow or outflow for the replanted scalp may become the only practical alternative and must not be overlooked. In this case, an arteriovenous shunt between the frontal branch of the superficial temporal artery within the amputated part itself to a more distal scalp vein at the superior edge of the fragment allowed high-output flow to maintain patency after recurrent thromboses of the conventional superficial temporal arterial anastomosis. This fistula was assumed to be the major contributor to nutrient flow of the remaining scalp, as the parietal branch was truncated along the margin of the avulsion. 3. Delayed tissue expansion is also an option. In this case, delayed expansion of the replanted scalp that survived allowed elimination of the skin grafts needed to cover areas where necrosis ensued, restoration of the anterior hairline, and resulted in a more normal appearance.     

Aneurysm of the superficial temporal artery presenting as a parotid mass

True aneurysms of the superficial temporal artery are rare and are associated with atherosclerosis. If the aneurysm occurs in the proximal portion of the superficial temporal artery, it may present as a parotid mass, encompass the facial nerve, and require superficial parotidectomy, as it did in this patient. Preoperative assessment with ultrasonography was the most useful diagnostic test because the aneurysm was thrombosed and was not visible by angiography. Thrombosed superficial temporal artery aneurysm should be in the differential diagnosis of parotid masses.     

Anatomical consideration of reverse-flow island flap transfers from the midpalm for finger reconstruction.

Primary soft-tissue coverage for large palmar defects of the fingers is a difficult problem for cases in which homodigital or heterodigital flaps cannot be used. The aim of this study was to explore the vascular and neural anatomy of the midpalmar area to assess the possibility of reverse island flaps from this area. In 24 cadaver hands perfused with a silicone compound, the arterial pattern of the superficial palmar arch and common palmar digital artery was examined. The cutaneous perforating arteries and nerve branches supplying the midpalmar area were dissected, and the number, location, and arterial diameter of these branches were measured. In six other specimens, the common palmar digital artery was injected to determine the skin territory supplied by the artery. The superficial palmar arch contained the three common palmar digital arteries and its terminal branch coursed along the radial margin of the index metacarpus. This terminal branch had three to six cutaneous perforators (diameter range, 0.1 to 0.5 mm) and supplied the radial aspect of the midpalmar area located over the ulnar half of the adductor pollicis muscles. The midpalmar area was divided into two regions-the proximal and distal-according to the vascular distributions. The proximal region contained dense aponeurosis and thin subcutaneous tissue, and the cutaneous perforators were rather sparse (between three and nine) and had a small diameter (0.1 to 0.3 mm). The distal region, which had loose aponeurosis and abundant subcutaneous tissue, had a rich vascular supply from the common and proper digital artery. Perforating arteries of this region coursed frequently in an oblique fashion and the number of perforators (between eight and 15) and their arterial diameters (diameter range, 0.1 to 0.5 mm) were higher than those of the proximal region. The area of skin perfused by the common palmar digital artery was 5 x 3 cm at the distal midpalmar region. There were three to five cutaneous nerve branches from the palmar digital nerve supplying the midpalmar area. From this study, two different reverse flaps were proposed. First, a 5 x 2 cm flap from the distal midpalmar region was elevated on the basis of the common and proper palmar digital artery. Measurement of the rotation arc revealed that the pivot point of this flap was located at the proximal interphalangeal joint level and could cover the finger pulp of the digits. The second flap candidate was that from the radial aspect of the midpalm, which was supplied by the terminal branch of the superficial palmar arch. In studies with cadaver hands, connection of this artery with the deep arterial system enabled this flap to reach the thumb pulp. These flaps may be a useful reconstruction option for significant palmar soft-tissue loss of the fingers.     

The vascular anatomy of the galeal flap in the interparietal and midline regions.

The potential extension of the galeal flap in the interparietal area was studied on 17 fresh human cadaver heads by intravascular dye injection technique. It was demonstrated that an ipsilateral superficial temporal artery that supplies the galeal flap does not cross the midline or anastomose with the contralateral superficial temporal artery but ensures the survival of a flap extended up to 1 cm proximal to the sagittal suture line. The width of the temporoparietal flap can be extended up to 15 cm, depending on the vascular pattern of the superficial temporal artery. When required, the lateral extension may provide the required soft-tissue bulk despite the reduced flap length.     

Island flap supplied by the dorsal branch of the ulnar artery

Two cases are reported in which a fasciocutaneous island flap was employed supplied by the ulnaris dorsalis artery after the method proposed by Becker and Gilbert. The original technique has been modified by the authors, and this produces a better venous outflow. The vascular pedicle includes, besides the ascending branch of the artery and the venae comitantes, one of the superficial veins together with its respective subdermal band. A technique is also described that provides an optimal length for the vascular pedicle.     

Axonal tracing of autonomic nerve fibers to the superficial temporal artery in the rat

Summary The origin of nerve fibers to the superficial temporal artery of the rat was studied by retrograde tracing with the fluorescent dye True Blue (TB). Application of TB to the rat superficial temporal artery labeled perikarya in the superior cervical ganglion, the otic ganglion, the sphenopalatine ganglion, the jugular-nodose ganglionic complex, and the trigeminal ganglion. The labeled perikarya were located in ipsilateral ganglia; a few neuronal somata were, in addition, seen in contralateral ganglia. Judging from the number of labeled nerve cell bodies the majority of fibers contributing to the perivascular innervation originate from the superior cervical, sphenopalatine and trigeminal ganglia. A moderate labeling was seen in the otic ganglion, whereas only few perikarya were labeled in the jugular-nodose ganglionic complex. Furthermore, TB-labeled perikarya were examined for the presence of neuropeptides. In the superior cervical ganglion, all TB-labeled nerve cell bodies contained neuropeptide Y. In the sphenopalatine and otic ganglia, the majority of the labeled perikarya were endowed with vasoactive intestinal polypeptide. In the trigeminal ganglion, the majority of the TB-labeled nerve cell bodies displayed calcitonin gene-related peptide, while a small population of the TB-labeled neuronal elements contained, in addition, substance P. In conclusion, these findings indicate that the majority of peptide-containing nerve fibers to the superficial temporal artery originate in ipsilateral cranial ganglia; a few fibers, however, may originate in contralateral ganglia.     

Depth of the facial nerve in face lift dissections

Facial nerve depth was measured in 12 cadaver face halves after bilateral face lift dissections. The main nerve trunk emerged anterior to the midearlobe and was 20.1 +/- 3.1 mm deep. Nerve exit from the parotid edge also was deep, averaging 9.1 +/- 2.8 mm for temporal, 9.2 +/- 2.2 mm for zygomatic, 9.6 +/- 2.0 mm for buccal, and 10.6 +/- 2.7 mm for mandibular branches. Distal to the parotid gland, danger areas where nerve branches became superficial were distal temporal, lower buccal, and upper mandibular branches over the masseter muscle and marginal mandibular as it crossed the facial artery. Some protection in these danger areas was provided by fascia, especially superficial temporal and masseteric, while platysma provided some protection for the mandibular branch. Fascial and muscle protection was less in thin cadavers. Face lift dissection can be rapid in areas where facial nerve branches are deep or absent, such as postauricular, inferior to the zygomatic prominence, and near the earlobe.     

An analysis of 123 temporoparietal fascial flaps: anatomic and clinical considerations in total auricular reconstruction.

This article presents an updated review of our experience with 122 temporoparietal fascial flaps, which were used for coverage of fabricated autogenous cartilage frameworks in total auricular reconstructions. Our indications for use of the temporoparietal fascial flap are presented. Partial flap necrosis occurred in 5 cases, total necrosis in 2 of 14 microsurgically transplanted cases, cartilage infection in 2 cases, and paralysis of the frontal branch of facial nerve in 1 case. Prospective observations of vascular anatomy were carried out in the last 93 temporoparietal fascial flaps during flap elevations. Only 59 flaps (63.4 percent) showed a typical pattern, distributed mainly by the superficial temporal artery and vein. Others (36.6 percent) were distributed mainly by various combinations of the posterior auricular artery or vein, occipital artery or vein, diploic vein, and the superficial temporal artery or vein. At the upper margin of the imaginary reconstructed auricle, the mean diameters of the artery and vein were 1.7 mm and 2.2 mm, respectively. There were no significant differences of vascular patterns and their diameters between the temporoparietal fascial flap of microtia sides and of nonmicrotia sides (sides with acquired ear deformities or free-flap donor sides). We are presenting our technical evolution in using the temporoparietal fascial flap for total auricular reconstruction with the goal of reducing surgical complications and improving aesthetic results.