Anatomy, Head and Neck, Scalp Veins


Article Author:
Alex Germann


Article Editor:
Yasir Al Khalili


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Ziad Katrib


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Mark Pellegrini
James Hughes
Beenish Sohail
Hajira Basit
Phillip Hynes
Sandeep Sekhon


Updated:
4/25/2019 3:44:14 PM

Introduction

The scalp refers to the skin layers and subcutaneous tissue that cover the cranium and is comprised of five layers: skin, dense connective tissue, epicranial aponeurosis, loose areolar connective tissue, and the periosteum. The first three layers move as one unit as they are tightly bound together. The veins of the scalp are present within the dense connective tissue, which also contains nerves and arteries, and the loose areolar connective tissue, which also contains emissary veins that connect to the diploic veins of the skull and the intracranial venous sinuses. 

The venous drainage of the scalp divides into superficial and deep. The superficial veins of the scalp, starting anteriorly and moving posteriorly, are the supratrochlear and supraorbital veins, respectively, the superficial temporal veins and its branches, the posterior auricular vein, and the occipital vein and its branches. The deep venous drainage is via the pterygoid venous plexus.

Structure and Function

Venous anatomy starts with a thick outer layer of connective tissue called the tunica externa or adventitia, a middle layer of smooth muscle called the tunica media, and an interior layer of endothelial cells called the tunica intima. As veins do not function like arteries in a primarily contractile manner and are not subject to the same kind of high pressures to which arteries are exposed, the smooth muscle layer of veins is less muscular than arteries. Veins also contain valves to prevent backflow.[1]

The veins of the scalp serve to drain the deoxygenated blood from the scalp muscles and back to the right heart via the internal and external jugular veins and the superior vena cava. As previously mentioned, there are also the valveless emissary veins that connect the superficial veins to intracranial venous sinuses and diploic veins of the skull.

Embryology

The scalp veins are derived from the mesoderm of the first and second branchial arches, embryologic structures that form between the fourth and seventh week of gestation. The branchial arches go on to form the blood vessels, bone, cartilage, and muscles of the face, among other structures.[2] The muscles that these veins drain also derive from the first and second branchial arches. Second branchial arch anomalies account for the majority (95%) of branchial arch anomalies, with first branchial arch anomalies accounting for only 1 to 4% of cases.[3]

Blood Supply and Lymphatics

We will describe the blood supply and lymphatics of the scalp veins starting with the superficial components anteriorly and moving posteriorly, beginning with the supratrochlear vein.

The supratrochlear vein originates on the forehead where it drains the superficial muscles and skin of the forehead and the front of the scalp supplied by the supratrochlear artery into the angular vein; there is no associated lymph tissue.

The supraorbital vein originates on the forehead and its anastomosis with the frontal branch of the superficial temporal vein and serves to drain the area of forehead, eyebrow, and upper eyelid supplied by the supraorbital artery that anastomoses with the frontal branch of the superficial temporal vein. The vein travels caudally over the frontal bone and superficial to the frontalis muscle before splitting to joining the supratrochlear vein inferiorly and the superior ophthalmic vein medially; it also has no associated lymph tissue.

The superficial temporal vein has frontal and parietal branches, serving to drain the superficial muscles and skin of the temporal region. It originates from a venous plexus on the side of the head and travels laterally from the temporal region over the zygomatic arch and entering the parotid gland to become the retromandibular vein where it joins the transverse facial vein. The retromandibular vein then drains into the internal jugular vein via its anterior branch, and the external jugular vein via its posterior branch. The frontal branch also connects to a parietal emissary vein that runs from the side of the head to the top of the head where it pierces the cranium and communicates with the superior sagittal sinus. The parietal branch anastomoses with the occipital vein. The parotid and auricular lymph vessels that are located both anteriorly and posteriorly of the superficial temporal vein and artery, and the superficial parotid and preauricular lymph nodes located posteriorly, drain the area supplied by the branches of the superficial temporal artery.

The posterior auricular vein assists with the draining of the muscles and skin of the scalp. It originates from small vessels behind the ear superficial to the temporal fascia and anastomoses with the occipital vein superiorly. It runs just behind the ear where it then confluences with the occipital and deep cervical veins, then receives blood from the posterior branch of the retromandibular vein before turning into the external jugular vein. The posterior auricular vein runs alongside the posterior auricular artery, which originates from the external carotid artery. It is surrounded anteriorly by the mastoid lymph nodes that drain into the parotid and auricular lymph vessels and posteriorly from sternocleidomastoid lymph nodes that drain into the occipital lymph vessels. These lymph vessels then drain into the jugular lymph vessels.

The occipital vein originates from small vessels on the posterior aspect of the scalp and drains the superficial muscles and skin of the occipital region. It is superficial to the occipital fascia and the occipital artery and anastomoses laterally with the parietal branch of the superficial temporal vein and inferolateral to the posterior auricular vein. It then runs into the inferior portion of the posterior auricular vein where it becomes the external jugular vein. The occipital vein also has an anastomosis with the intracranial confluence of the sinuses via the occipital emissary vein. The occipital lymph nodes and vessels drain lymph from this area and drain into the jugulodigastric lymph node, which drains into the jugular lymph vessels.

The venous drainage of the deep scalp layers is via the pterygoid venous plexus, an extensive plexus of veins located between the lateral pterygoid and temporalis muscles, draining into the maxillary vein. It receives branches corresponding with the branches of the maxillary artery. These veins include:

  • Alveolar
  • Buccinator
  • Deep temporal (anterior and posterior)
  • Infraorbital
  • Masseteric
  • Middle meningeal
  • Pterygoid
  • Sphenopalatine

The pterygoid venous plexus also receives blood from some branches of the palatine veins and contains a communicating vein that travels through the inferior orbital fissure to connect the ophthalmic vein to the cavernous sinus.

Nerves

Again, working our way anteriorly to posteriorly, we will list the nerves that are present near the scalp veins.

The supratrochlear nerve is located medially of the supratrochlear vein, whereas the medial branch of the supraorbital nerve is just deep to the supratrochlear vein.

The lateral branch of the supraorbital nerve is just medial and deep to the supraorbital vein.

The temporal branches of the facial nerve are located between the zygomatic orbital vein (a non-scalp vein) inferiorly, and the frontal branch of the superficial temporal vein superiorly and posteriorly.

The auriculotemporal nerve runs just anterior and deep to the superficial temporal artery and vein.

The posterior auricular artery and vein are sandwiched between the posterior auricular nerve anteriorly and the great auricular nerve just deep and posteroinferiorly.

Sandwiching the occipital artery and vein are the lesser and greater occipital nerve branches, superficially and anteriorly, and posteriorly, respectively.

Muscles

The scalp veins primarily drain the deoxygenated blood from the epicranial aponeurosis and the frontal and occipital belly of the occipitofrontalis muscle, the temporalis muscle, the auricularis superior muscle, the temporoparietalis muscle, the auricularis anterior muscle, and the auricularis posterior muscles.

Physiologic Variants

The parietal emissary vein most commonly communicates with the superficial temporal vein, specifically the frontal branch, but may communicate with other scalp veins. The occipital emissary vein may not be present in all individuals. The multiple anastomoses of the scalp may also have variability in what branches of what veins interconnect.

Clinical Significance

Deep lacerations to the scalp are inclined to bleed profusely for several reasons:

  • Vasoconstriction is prevented due to the close-fitting adherence of the dense connective tissue to the blood vessels
  • The pulling effect of the occipitofrontalis muscle precludes the closing of the actively bleeding vessel and the surrounding skin
  • There are numerous anastomoses of the scalp blood vessels, such as the anastomosis of the occipital and the posterior auricular veins

Scalp arteriovenous malformations (AVM), or cirsoid aneurysms, are uncommon lesions whose etiologies are most commonly congenital, post-infectious, or traumatic.[4] These AVMs often comprise arterial blood from the superficial temporal or occipital arteries and venous outflow into extracranial venous structures. Treatment of AVMs typically consists of endovascular embolization, which is followed by surgical resection; therefore, variant arterial supply, as well as venous drainage, should be considered in these cases.

Subgaleal hematoma (SGH) is an abnormal collection of blood beneath the galea aponeurosis of the scalp, commonly caused by traumatic shearing of emissary veins in the loose areolar tissue. This condition is more commonly seen in neonates, infants, and small children, although there have been case reports of SGHs occurring in adults. [5] Mild trauma typically occurs via contusion, hair pulling, or vacuum-assisted vaginal delivery. Treatment is conservative management with bandage compression.

The ‘danger area of the scalp’ refers to the layer of loose areolar connective tissue as it contains the valveless emissary veins that connect the superficial veins in the subaponeurotic space with the intracranial venous sinuses. This connection makes it possible for an infection to spread from the scalp to the meninges.

Cavernous sinus thrombosis is the development of a blood clot within the cavernous sinus. The cavernous sinus is one of the dural venous sinuses, a cavity at the base of the brain that helps drains deoxygenated blood from the brain via the superior and inferior ophthalmic veins, the superficial middle cerebral veins, the sphenoparietal sinus, and the inferior cerebral veins. The cavernous sinus has connections to the pterygoid venous plexus via the inferior ophthalmic vein, deep facial vein, and emissary veins. Due to this connection, superficial facial infections from the nose, sinuses, ears, or teeth may spread to the cavernous sinus to cause this disorder. Symptoms may include proptosis, unilateral periorbital edema, decrease or loss of vision, headaches, and possible cranial nerve paralysis, particularly of the delicate abducens nerve that runs through the cavernous sinus. There are two types of cavernous sinus thromboses: septic and aseptic. Treatment of septic disease includes initial broad-spectrum IV antibiotics covering staph and strep, the most commonly associated bacteria, then a prolonged course (3 to 4) weeks of targeted IV antibiotics. Surgical drainage may be necessary in cases of sphenoidal sinus infection.[6]

Scalp veins may be used for venous catheterization as they offer easy access with little risk.[7] Most commonly, scalp catheterization is utilized in infants and neonates after unsuccessful attempts at cannulation of extremity veins as the scalp veins in this population have less overlying subcutaneous fat and are more prominent compared to other peripheral sites, and they are less obscured by hair. These factors allow for easier visualization and therefore cannulation. The most commonly used veins are the superficial temporal, the supratrochlear, and occipital veins.


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An anatomy student is dissecting the lateral face during an anatomy class and has identified a venous structure that lies between the lateral pterygoid and temporalis muscles. From which of the following structures does this venous plexus receive blood drainage?



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A 3-year-old girl is brought to the ED following a motor vehicle accident. The patient has lost a lot of blood as she is pale, tachycardic, and hypotensive. The patient has sustained a scalp laceration just behind her ear. Which of the following veins is most likely to be injured?



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A 56-year-old female sustains a posterior scalp laceration in a motor vehicle accident. Dark red blood is actively oozing out of the wound. The vein that is most likely injured drains into which of the following structures?



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A 12-year-old boy falls and hits his upper lateral neck on the corner of a coffee table, sustaining a laceration to a vessel superficial to the sternocleidomastoid muscle. What area of the scalp does the most likely injured vein drain?



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Anatomy, Head and Neck, Scalp Veins - References

References

Scalp Arteriovenous Malformation (Cirsoid Aneurysm) in Adolescence: Report of 2 Cases and Review of the Literature., Li D,Heiferman DM,Rothstein BD,Syed HR,Shaibani A,Tomita T,, World neurosurgery, 2018 Aug     [PubMed]
Subgaleal Hematoma at the Contralateral Side of Scalp Trauma in an Adult., Chen CE,Liao ZZ,Lee YH,Liu CC,Tang CK,Chen YR,, The Journal of emergency medicine, 2017 Nov     [PubMed]
Matthew TJH,Hussein A, Atypical Cavernous Sinus Thrombosis: A Diagnosis Challenge and Dilemma. Cureus. 2018 Dec 4;     [PubMed]
Doyle TD,Edens MA, Scalp Catheritization 2019 Jan;     [PubMed]
Adams A,Mankad K,Offiah C,Childs L, Branchial cleft anomalies: a pictorial review of embryological development and spectrum of imaging findings. Insights into imaging. 2016 Feb;     [PubMed]
Koeller KK,Alamo L,Adair CF,Smirniotopoulos JG, Congenital cystic masses of the neck: radiologic-pathologic correlation. Radiographics : a review publication of the Radiological Society of North America, Inc. 1999 Jan-Feb;     [PubMed]
Bechmann S,Kashyap V, Anatomy, Head and Neck, External Jugular Veins . 2019 Jan     [PubMed]

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