INTERNATIONAL JOURNAL OF SURGICAL PROCEDURES (ISSN:2517-7354)

Arteriovenous malformations (AVMs) are congenital high- flow vascular malformations that lack the normal capillary beds shunting blood from the arterial system to the venous system. They are often misdiagnosed at birth as other vascular lesions because of the delay in presentation of the characteristic signs of the malformations. Puberty and trauma trigger the growth of the lesion and manifestation of its troublesome symptoms. They are infiltrative causing destruction of local tissue and often life-threatening secondary to massive bleeding. Extracranial AVMs are different from their intracranial counterpart and are found in several areas in the cervicofacial region. This article highlights the pathogensis, classification of arteriovenous malformations with an emphasis on the updates in diagnostic and treatment modalities.

Vascular anomalies are a group of lesions derived from blood vessels and lymphatic with widely varying histology and clinical behavior. They constitute the most common congenital abnormalities in infants and children. James Wardrop, a London surgeon, first recognized the differences between true hemangiomas and the less common vascular malformations in 1818. Despite Dr. Wardrop’s work, descriptive identifiers such as strawberry hemangioma and salmon patch continued to be used until the 1980s. This terminology, in fact, did not correlate with either the biological behavior or the histological patterns of these lesions. In 1982, Mulliken and Glowacki [1] greatly advanced the field by introducing a biological classification which differentiated vascular lesions into two distinct entities: hemangiomas and vascular malformation. Arterivenous malformations, either intracranial or extracranial, were referred to by Mulliken and Glowacki as a subdivision of the vascular malformations group.

Arteriovenous malformations are caused by an abnormal connection between an artery and a vein, in which, the first portion of the distal vein is known as the nidus [2]. Although, arteriovenous malformations are relatively rare, they represented a challenge to the surgeons not only in relation to early detection and proper diagnosis, but also in available management options as improper treatment may be accompanied by high morbidity and poor outcomes. Therefore, and due to their complexity, a multidisciplinary approach is frequently necessary in managing these lesions and includes a team of specialists [3,4]. Around half of all extracranialarteriovenous malformations affect the head and neck [5] and a slight female predominance (1:1.5) has been reported [6]. Thus, the current article reviews the updates on recent developments in the diagnosis, management, and pathogenesis of arteriovenous malformations affecting the maxillofacial region.

Both vascular tumors and malformations may occur anywhere on the body. In brief, hemangiomas are vascular tumors that are rarely apparent at birth, grow rapidly during the first six months of life, involute with time and do not necessarily infiltrate but can sometimes be destructive. Vascular malformations are irregular vascular networks defined by their particular blood vessel type. In contrast to hemangiomas, they are present at birth, slow growing, infiltrative, and destructive. Almost all vascular malformations and nearly 40% of hemangiomaseventually require intervention [6,7]. 

At the cellular level, lesions do not show the abnormal growth of endothelial cells seen in vascular tumors, and angiogenesis and vasculogenesis are thought to account for their expansion. Increased blood flow can cause collateralization, dilatation of existing vessels and thickening of adjacent vesselsand increased pressure is thought to stimulate cellular hypertrophy [6,11].Increased levels of matrix metalloproteinase (MMP) have also been found in the tissue and the urine of patients with active lesions and a similar possible role has been suggested [15,16]. However, despite ongoing recognition and understanding of the genetic mutations that result during the development and progression of lesions, the identification of precise therapeutic targets seems daunting. Research into cerebral lesions has shown that over 860 different genes are up-regulated or downregulated in them [17].

Several methods of clinical and radiological classification have been advocated, including a classification by Houdart et al, [19]which was introduced in 1993 based on the number of arterial and venous communications and niduses.This classification was further modified by Cho et al. [20] in 2006 with a highlighting on the potential outcome (Table 2).

The International Society for the Study of Vascular Anomalies (ISSVA) introduced an updated classification in 2018 to clarify the ambiguous nomenclature that frequently causes miscommunication and confusion among clinicians [21].

Anatomically, five types of extracranialarterivenous malformations were reported, mucous/cutaneous (type I), submucosal/subcutaneous (type II), glandular (type III), intraosseous (type IV) and deep visceral (type V). Subsequently, various treatment modalities were suggested based on the anatomical location of the lesion [22].

The natural and most common course of arteriovenous malformation is early quiescence, late expansion, and ultimately infiltration and destruction of local soft tissue and bone. Common sites for occurence are the midface, oral cavity, and limbs. Oral lesions can present early due to gingival involvement, disruption of deciduous teeth, and profuse periodontal bleeding [6].

Arteriovenous malformations (AVMs) of the jaws are relatively rare, with fewer than 200 cases reported in the literature. Their real importance lies in their potential to result in exsanguination, which usually follows an unrelated treatment, such as tooth extraction, surgical intervention, puncture wound or blunt injury in involved areas, with the dentist unaware of the existence of the AVM [24].

Ultrasound, magnetic resonance imaging (MRI), and angiography are used to investigate the morphology and to plan treatment. Lesions have multiple vascular channels on ultrasonography, and Doppler studies show high flow and loss of normal venous damping [27].Their size, shape, and association with neighboring tissue show well on MRI and MRA. Angiography, usually digital subtraction angiography (DSA) is always required to identify the detailed vascular anatomy (Figure 3). Angiography typically shows dilated and tortuous feeding arteries, arteriovenous shunts, and greatly dilated draining veins with a good definition of central nidus of affected vessels which provide access for intravascular treatment when necessary [28].

The angioarchitectural features of an arteriovenous malformation provide key information regarding natural history and treatment planning. Because of rapid filling and vascular overlap, two-dimensional (2D) and three-dimensional (3D) digital subtraction angiography (DSA) are often suboptimal for evaluation of these features. A feasibility study by Sandoval-Garcia et al., [29] in 2016 developed an algorithm that derives a series of fully timeresolved four-dimensional volumes (4DDSA) at up to 30 frames/s from a conventional 3D DSA. They assumed that the temporal/spatial resolution of 4D reconstructions is significantly higher than that provided by current MR angiography and CT angiography techniques. 4D reconstruction allows viewing of an AVM from any angle at any time during itsopacification (Figure 4). Because of the limited number of cases included in this study (six cases), further experience is required to determine the ultimate utility of this technique.

Treatment is challenging, and an interdisciplinary approach and extensive clinical experience are recommended.It aims to control shunting and to palliate the clinical manifestations. When available, endovascular approaches are currently considered the first line of treatment, and are often combined with resection of focal lesions or those with a well localized nidus. Unfortunately, diffuse lesions are less easy to treat, and multiple staged procedures are often done to prevent excessive damage to local tissue and to contain recurrent disease early. In many cases, treatment is not curative, and it aims to palliate by down-grading the lesion and decreasing the risk of potentially life-threatening complications and further disfigurement. Given the side effects and potential problems of treatment, intervention is often reserved for progressive lesions of Schobinger stage 2 and above. Taking into consideration that the fundamental principle in the treatment of all arteriovenous malformations is complete removal [13].

Although the effective surgical management of high flow lesions without preoperative embolisation has been described, for instant, Nair et al., [22] reported the use of external carotid control combined with surgical resection in a series of 115 patients with arteriovenous malformations despite their accepted success rate the technique did not gain popularity among the clinicians. Instead,resection after embolisation has become the most accepted treatment. Preoperative embolisation can help delineate the extent of a lesion and dramatically reduce intraoperative bleeding, and multiple embolisations before operation have been found to lessen the risk of recurrence [30]. 

The technique for selective intra-arterial embolization have been described by Zhao et al., [32] they used the Seldingercatheterisation technique for digital selective angiography through the femoral artery. The catheter was passed into the common carotid artery, and angiographs of the external and internal carotid arteries were taken to show the arteriovenous malformations (AVMs) in thirteen cases within the maxillofacial region. The origin of each feeding artery (facial, superior temporal, and lingual arteries) was embolised individually. The angiogram after embolisation showed obviously reduced blood flow, (Figure 5) and the colour of the skin over the AVM was clinically normal. The soft tissue pulsation decreased. The catheter was removed after embolisation, and the puncture site compressed with a bandage. Typically, surgical excision was performed 24-48 hours following the embolization [31,32].

Embolisation material: The ideal anabolic agent, which should be safe and allow controlled deployment, would fully penetrate the nidus and draining veins and give a permanent occlusion. Historically, coils, plugs, and liquids were used, but newer semi-liquid, chemical, embolic agents are now available. Modern agents consist of nonadherent copolymers dissolved in a solvent that gives greater flow. Additions such as tantalum (Onyx®, ev3 Endovascular Inc, Covidien, Plymouth, USA) and iodine (PHIL^TM, MicroVention Europe SARL, Saint- Germainen-Laye, France) giveradiopacity, which allows real time, controlled delivery of fluoroscopic images [31,33]. 

Onyx® is a liquid embolic agent that is dissolved in dimethyl sulphoxide (DMSO) and opacified by tantalum powder. It became popular as a neurovascular embolic agent, and has recently been used in peripheral lesions. On contact with blood, the DMSO diffuses out of the mixture and leaves the ethyl vinyl alcohol to polymerise. Polymerisation first occurs peripherally within the mixture, and over a few minutes gradually hardens towards the center of the plug.This extends the working time and allows more time for the injection. Once hardened, Onyx® leaves a rigid cast that plugs the nidus permanently, and gives a characteristic appearance on future imaging. However, its use is not without complications. DMSO is an irritant that can cause serious local and perivascular inflammation that can potentially damage otherwise healthy tissue, and the black tantalum powder can stain the adjacent skin. Coloration can help to define the extent of embolization at resection of a lesion obliterated with Onyx®, and characteristic sparking occurs upon contact with diathermy. As with any embolic agent, misplacement can lead to hypoxia, and can damage otherwise normal structures, and result in blindness or stroke [33].

PHIL^TM (precipitating hydrophobic injectable liquid) is a new embolic agent that is being used in the endovascular management of cerebral neurovascular diseases. Three concentrations are available, with various viscosities and different flow characteristics that lead to deeper penetration of the nidus. As the material looks white on clinical inspection, the risk of staining is minimalized. The benefits of PHIL^TM are now being recognized in the management of extracranial arteriovenous malformations, with successful endovascular embolisation and subsequent resection. Like Onyx®, PHIL^TM also uses the solvent DMSO, and therefore has the same risk of perivascular inflammation and tissue damage, but it also has the less dangerous side-effect of a garlic-like odour from the breath and skin of patients. Patients may also report a garlic-like taste [31,32].

The treatment of hereditary haemorrhagic telangiectasia is progressing [38]. Patients with this autosomal dominant condition develop multiple telangiectases and arteriovenous malformations of the solid organs through disregulated angiogenesis. Bevacizumab, a humanized anti-Vascular Endothelial Growth Factor (anti-VEGF) antibody, has shown promising results in early clinical trials to control nosebleedsand arteriovenous malformations of the liver [39]. Side effects include hypertension, severe proteinuria, decreased wound healing, and gastrointestinal bleeding [40], and its effect on cutaneous and cerebral lesions is as yet unknown. Thalidomide, together with its second generation successor lenalidomide, has antiangiogenic properties as well as immunomodulatory effects. Both have been shown anecdotally to control bleeding from gastrointestinal lesions,although their role in cutaneous lesions has not been reported [41,42].

Radiosurgery is used with increasing frequency, not only for the treatment of cerebral arteriovenous malformations (AVMs), but also for the treatment of other well-defined lesions including acoustic neuromas, meningiomas, pituitary adenomas as well as solitary metastases [45]. Although investigators have addressed dosimetric aspects of stereotactic radiosurgery in terms of target volume, little if any attention has been focused on the absorbed doses received at extracranial sites. Therefore, the treatment of extracranial arteriovenous malformations using radiosurgery did not gain popularity among clinicians and its use was limited for management of other vascular anomalies such as haemagiomas [46]. 

The risk of re-expansion and recurrence after intervention is thought to be similar to factors that result in the progressive expansion of a lesion, and it is well known that embolic and surgical treatments can stimulate recurrence through the creation of a proangiogenic environment [31].

Embolisation leads to local hypoxia and increased levels of vascular endothelial growth factor (VEGF), Meanwhile, Operation and healing also induce local hypoxia and inflammation, which are known stimulants of angiogenesis through VEGF, basic fibroblast growth factor, and matrix metalloproteinase (MMP) [47]. To reduce hypoxia and recurrence after resection, several authors have proposed reconstruction with free-tissue transfer [48]. However, these studies were short term, and those that reported a longer period of follow up have not shown significantly lower recurrence after free tissue reconstruction [49].

In conclusion, no accepted single method for treatment of arteriovenous malformations has been identified. Simple focal lesions are usually managed properly by embolization followed by surgical excision of the lesions. Meanwhile, more diffuse lesions are more difficult to treat and usually require a multidisciplinary approach. Taking into consideration that guaranteed curative intervention must include resection if technically possible. Given the difficulty in establishing surgical margins and the need for wide resection, it is important to remember to avoid a treatment that is even worse than the disease.

1. Mulliken JB, Glowacki J. Hemangiomas and vascularmalformations in infants and children: a classification basedon endothelial characteristrics. Plast Reconstr Surg. 1982Mar:69(3):412-422.
2. Marler JJ, Mulliken JB. Vascular anomalies: classification,diagnosis and natural history. Facial Plast Surg Clin North Am.2001 Nov:9(4);495-504.
3. Monaghan A, McCafferty I, Lamin S, Nishikawa H, Williams R. The effective management of high flow vascular malformations of the head and neck. Br J Oral Maxillofac Surg 2009;47:e42-e43.
4. Richter GT, Friedman AB. Hemangiomas and VascularMalformations: Current Theory and Management. Int J Pediatr.2012;2012:645678.
5. Greene AK, Orbach DB. Management of arteriovenous malformations. ClinPlast Surg. 2011;38:95-106.
6. Kohout MP, Hansen M, Pribaz JJ,Mulliken JB. Arteriovenousmalformations of the head and neck: natural history andmanagement. Plast Reconstr Surg.1998;102(3):643-654.
7. Motamedi MH, Behnia H, Motamedi MR. Surgical technique forthe treatment of high-flow arteriovenous malformations of themandible. J Craniomaxillofac Surg. 2000;28(4):238-242.
8. Corti P, Young S, Chen CY, Patrick MJ, Rochon ER, et al. Interactionbetween alk1 and blood flow in the development ofarteriovenousmalformations.Development. 2011;138(8):1573-1582.
9. Kim H,Su H, Weinsheimer S, Pawlikowska L, Young WL. Brainarteriovenous malformation pathogenesis: a response-to-injuryparadigm. Acta Neurochir Suppl. 2011;111:83-92.
10. Duyka LJ, Fan CY, Coviello-Malle JM, Buckmiller L, Suen JY.Progesterone receptors identified in vascular malformationsof the head and neck. Otolaryngol Head Neck Surg.2009;141(4):491-495.
11. Connors JP III, Mulliken JB. Vascular tumors and malformations in childhood. In: Rutherford RB, ed. Vascular Surgery, vol. 2, 6th ed. Elsevier Saunders, 2005, Pp 1626-1645.
12. Enjolras O, Logeart I, Gelbert F, Lemarchand-Venencie F, ReizineD, et al. Arteriovenous malformations: a study of 200 cases. AnnDermatol Venereol.2000 Jan;127(1):17-22.
13. Uller W, Alomari AI, Richter GT. Arteriovenous malformations. Semin Paediatr Surg. 2014;23:203-207.
14. Liu AS, Mulliken JB, Zurakowski D, Fishman SJ, Greene AK.Extracranial arteriovenous malformations: natural progressionand recurrence after treatment. Plast Reconstr Surg.2010;125(4):1185-1194.
15. Hashimoto T, Matsumoto MM, Li JF, Lawton MT, Young WL.Suppression of MMP-9 by doxycycline in brain arteriovenousmalformations. BMC Neurol. 2005;5:1-5.
16. Marler JJ, Fishman SJ, Kilroy SM, Fang J, Mulliken JB,et al.Increased expression of urinary matrix metalloproteinasesparallels the extent and activity of vascular anomalies. Pediatrics.2005 Jul;116(1):38-45.
17. Rangel-Castilla L, Russin JJ, Martinez-Del-Campo E, SorianoBaron H, spetzler RF, et al. Molecular and cellular biology ofcerebral arteriovenous malformations: a review of currentconcepts and future trends in treatment. Neurosurg Focus.2014;37(3):e1-e6.
18. Richter GT, Suen JY. Pediatric extracranial arteriovenousmalformations. Otolaryngol Head Neck Surg. 2011;19(6):455-461.
19. Houdart E, Gobin YP, Casasco A, Aymard A, Herbreteau D,et al. A proposed angiographic classification of intracranialarteriovenous fistulae and malformations. Neuroradiology.1993;35(5):381-385.
20. Cho SK, Do YS, Shin SW, Kim DJ, Kim YM, et al. Arteriovenousmalformations of the body and extremities: analysis oftherapeutic outcomes and approaches according to a modifiedangiographic classification. J Endovasc Ther. 2006;13(4):527-538.
21. Monroe EJ. Brief description of ISSVA classification forradiologists.Tech Vasc Interv Radiol. 2019;22(4):100628.
22. Nair SC, Spencer NJ, Nayak KP, Balasubramaniam K. Surgicalmanagement of vascular lesions of the head and neck: a reviewof 115 cases. Int J Oral Maxillofac Surg. 2011;40(6):577-583.
23. Mulligan PR, Prajapati HJS, Martin LG, Patel TH.Vascularanomalies: classification, imaging characteristics andimplications for interventional radiology treatment approaches.Br J Radiol. 2014 Mar;87:1035-1042.
24. Shailaja SR, Manika K, Manjula M, Kumar LV. Arteriovenousmalformation of the mandible and parotid gland. DentomaxillofacRadiol. 2012 Oct;41(7):609-614.
25. Ziyeh S, Strecker R, Berlis A, Weber J, Klisch J, et al. Dynamic3D MR angiography of intra- and extracranial vascularmalformations at 3T: a technical note. AJNR Am J Neuroradiol.2005;26(3):630-634.
26. Tao Q, Lv B, K Bhatia SS, Qiao B, Zheng CQ, et al. Threedimensional CT angiography for the diagnosis and assessmentof arteriovenous malformations in the oral and maxillofacialregion. J Craniomaxillofac Surg. 2010;38(1):32-37.
27. Legiehn GM, Heran MK. Classification, diagnosis, andinterventional radiologic management of vascularmalformations. Orthop Clin North Am. 2006;37(3):435-474.
28. McCafferty IJ, Jones RG. Imaging and management of vascularmalformations. Clin Radiol. 2011;66(12):1208-1218.
29. Sandoval-Garcia C, Royalty K, Yang P, Niemann A, Ahmed A, etal. 4D DSA a new technique for arteriovenous malformationevaluation: a feasibility study.J Neurointerv Surg. 2016;8(3):300-304.
30. Goldenberg DC, Hiraki PY, Caldas JG, Puglia P, Marques TM, et al.Surgical treatment of extracranial arteriovenous malformationsafter multiple embolizations: outcomes in a series of 31 patients.Plast Reconstr Surg. 2015;135(2):543-552.
31. Fowell C, Jones R, Nishikawa H, Monaghan A. Arteriovenousmalformations of the head and neck: current concepts inmanagement. Br J Oral Maxillofac Surg. 2016;54(5):482-487.
32. Zhao X, Huang Z, Chen W, Wang Y, Lin Z. Percutaneoussclerotherapy of arteriovenous malformations of the faceusing fibrin glue combined with OK-432 and bleomycin afterembolization. Br J Oral Maxillofac Surg. 2016;54(2):187-191.
33. Lazzaro MA, Badruddin A, Zaidat OO, Darkhabani Z, Pandya DJ,et al. Endovascular embolization of head and neck tumors. FrontNeurol. 2011;2:64-70.
34. Lapresta A,Hermosa E,Boixeda P, Carrillo-Gijón R.AcquiredDigital Arteriovenous Malformations: Laser Treatment OfAn Uncommon Vascular Abnormality. Actas Dermosifiliogr.2014;105(5):e33-e37.
35. Bekhor PS, Ditchfield MR. Acquired digital arteriovenous malformation: Ultrasound imaging and response to long-pulsedneodymium:yttrium-aluminum-garnet treatment. J Am AcadDermatol. 2007;56(5 Suppl):S122-S124.
36. Sparano JA, Bernado P, Stephenson P, Gradishar WJ, Ingle JN, etal. Randomized phase III trial of marimastat versus placebo inpatients with metastatic breast cancer who have responding orstable disease after first-line chemotherapy: Eastern CooperativeOncology Group trial. J Clin Oncol. 2004;22(23):4683-4690.
37. Burrows PE, Mulliken JB, Fishman SJ, Klement GL, FolkmanJ. Pharmacological treatment of a diffuse arteriovenousmalformation of the upper extremity in a child. J Craniofac Surg.2009;20:597-602.
38. Dupuis-Girod S, Ambrun A, Decullier E, Samson G, Roux A, etal. ELLIPSE Study: a Phase 1 study evaluating the toleranceof bevacizumab nasal spray in the treatment of epistaxis inhereditary hemorrhagic telangiectasia. MAbs. 2014;6(3):794-799.
39. Dupuis-Girod S, Ginon I, Saurin J, Marion D, Guillot E, etal. Bevacizumab in patients with hereditary hemorrhagictelangiectasia and severe hepatic vascular malformations andhigh cardiac output. JAMA. 2012;307(9):948-955.
40. Pavlidis ET, Pavlidis TE. Role of bevacizumab in colorectal cancergrowth and its adverse effects: a review. World J Gastroenterol.2013;19(31):5051-5060.
41. Perez Botero J, Burns D, Thompson CA, Pruthi RK. Successfultreatment with thalidomide of a patient with congenital factor Vdeficiency and factor V inhibitor with recurrent gastrointestinalbleeding from small bowel arteriovenous malformations.Haemophilia. 2013;19(1):e59-e61.
42. Bowcock S, Patrick HE. Lenalidomide to control gastrointestinalbleeding in hereditary haemorrhagic telangiectasia:potential implications for angiodysplasias. Br J Haematol.2009;146(2):220-222.
43. Brada M. How effective is radiosurgery for arteriovenousmalformations?. Journal of Neurology, Neurosurgery &Psychiatry. 2000;68:548-549.
44. Kurita H, Kawamotoa S, Sasakia T, Shina M, Tagob M, et al. Resultsof radiosurgery for brain stem arteriovenous malformations. JNeurolNeurosurg Psychiatry. 2000 May;68(5):563-570.
45. Berk HW, Larner JM, Spaaulding C, Agarwal SK, Scott MR, et al.Extracranial absorbed doses with Gamma Knife radiosurgery.Stereotact Funct Neurosurg. 1993;61(1):164-172.
46. Fowell C, Monaghan A, Nishikawa H. Infantile haemangiom wasof the head and neck: current concepts in management. Br J OralMaxillofac Surg. 2016;54(5):488-495.
47. Lingen MW. Role of leukocytes and endothelial cells in thedevelopment of angiogenesis in inflammation and woundhealing. Arch Pathol Lab Med. 2001;125(1):67-71.
48. Yamamoto Y, Ohura T, Minakawa H, Sugihara T, Yoshida T, et al.Experience with arteriovenous malformations treated with flapcoverage. Plast Reconstr Surg. 1994;94(3):476-482.
49. Hartzell LD, Stack BCJr, Yuen J, Vural E, Suen JY. Free-tissuereconstruction following excision of head and neck arteriovenousmalformations. Arch Facial Plast Surg. 2009;11(3):171-177.