Intraosseous Cranial Dural Arteriovenous Fistula Treated with Transvenous Embolization

Materials and Methods

Six patients (M/F, 4:2; mean age, 58.6 years; age range, 15–82 years) with intraosseous DAVFs were treated by endovascular techniques in the 3 hospitals and composed the study population. The demographic profiles, symptoms, and signs are summarized in the on-line Table. The patients had different symptoms and signs of a variable duration, but pulsatile tinnitus was the most frequent symptom. Case 1 presented with diplopia and ptosis indicating that the lesion was located at the cavernous sinus. Case 2 had hearing loss at 4 months before admission, which was not a usual symptom for the presence of DAVF.

In all of these patients, we retrospectively reviewed medical records and images for an anatomic analysis of the lesions and the clinical outcomes after endovascular treatment. There were preprocedural CT, MR imaging, and conventional angiographic images available for all these patients. We determined immediate angiographic outcome as residual shunt or complete occlusion after treatment, whether or not residual shunt remained. Follow-up anatomic outcome was evaluated by MR angiography (MRA) or conventional angiography. Follow-up MRA or conventional angiography was available in 5 patients, but there was no follow-up MRA or angiography in 1 patient (case 6).

Results

Angiographic Details of Intraosseous DAVFs

We were able to confirm the presence of an intraosseous DAVF in all the patients with the use of CT, MR imaging, and cerebral angiography. The abnormal dilated venous sac within the bone was demonstrated on the CT and MR images, including time-of-flight MRA (TOF-MRA) or coronal source images of 3D rotational angiography (Figs 1D–H and 2E and F). In all of the cases, CT or MR imaging showed the dilated venous pouch within the bone. The lesions were manifest as osteolytic lesions within the bony structure as seen on noncontrast CT images with the bone window setting (Figs 1A and 2A), and the dilated venous pouch as seen with a signal-intensity void on MR images (Fig 1B).

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Fig 1.

Case 3. Axial noncontrast CT scans with a bone window setting (A) and a T2-weighted axial MR image (B) show the osteolytic lesion and signal-intensity void, respectively (white arrow), which correspond to the intraosseous venous pouch (asterisks in D and E) and are located at the lower clivus around the hypoglossal canal (double arrow in D). Selective angiography of the right ascending pharyngeal artery (C) and coronal reconstructed images of rotational angiography (D−G) show a fistula between the artery and dilated venous pouch (arrowhead in E) and venous drainage into vertebral venous system, such as the venous plexus, around the horizontal segment of the vertebral artery (dotted arrow) via the posterior condylar vein (open arrow in C and F). After transvenous embolization, coil was packed within the dilated venous pouch (H).

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Fig 2.

Case 6. The intraosseous venous pouch (arrows in A and B) was located at the left lower clivus around the hypoglossal canal, and selective angiography of the ascending pharyngeal artery confirmed an arteriovenous shunt (C), which was more correctly localized by the contralateral common carotid angiography (D). The venous connection (open arrowhead) between the intraosseous venous pouch and the internal jugular vein (double arrows) was so obvious on the coronal reconstructed image of rotational angiography (E) that the intraosseous venous pouch and venous connection could be completely occluded by the transvenous embolization (F).

MRA was performed for the all patients except for case 2, and imaging showed the presence of an arteriovenous shunt around the abnormal dilated venous sac. The lesions were located at the upper clivus, petrous apex, or lower clivus around the hypoglossal canal. The most common location of a lesion was the lower skull base around the hypoglossal canal in 4 patients. Conventional angiography showed the arteriovenous shunt in the wall of the abnormally dilated venous pouch. In 2 patients, the osseous lesions were clearly demonstrated on the coronal reconstructed images of 3D rotational angiography (Integris Allura; Philips Medical Systems, Best, the Netherlands).

As seen on angiography, the intraosseous DAVFs were predominantly fed by the meningeal branches, such as the ascending pharyngeal artery, occipital artery, meningohypophyseal trunk of the internal carotid artery (ICA), and the anterior meningeal artery from the vertebral artery, as expected. The subarcuate artery from the anterior inferior cerebellar artery (AICA) supplied the lesion in case 2. These feeding arteries were focused on the wall of the dilated venous pouch, which was considered the target area of treatment. In cases 3 and 6, coronal source images of 3D rotational angiography demonstrated that the fistula was located at the wall of the dilated venous pouch (Fig 1E).

The dilated venous pouch was located within the bone and communicated with venous structures around the lesions (Figs 1F and 2E). In cases 1 and 4, the DAVFs showed retrograde venous reflux into the cavernous sinus via the inferior petrosal sinus (IPS), which also resulted in leptomeningeal and superior ophthalmic reflux. In cases 3 and 5 in which the lesions were located around the hypoglossal canal, shunt flows drained into the prevertebral and internal epidural venous plexus of the spine via the transosseous emissary vein, the so-called anterior and posterior condylar vein. There was perimedullary reflux via the internal epidural venous plexus in case 5. Cases 1 and 4 showed cortical venous drainage by the reflux via the IPS and cavernous sinus.

Discussion

DAVF can be defined as an abnormal shunt between the meningeal artery and vein or sinus or both within the dura.^1–4 The term “intraosseous DAVF” may be a misnomer and “intraosseous AVF” might be more accurate.³ Malik et al⁸ first described 2 cases of DAVFs that were treated by surgical excision. The lesions were completely removed by resection of the pathologic bony portion. The lesion of the “intraosseous DAVF” had the nidus exclusively located within the bone, with a venous drainage pattern similar to that of a classic DAVF as seen on angiography.

Geibprasert et al¹⁴ recently defined DAVFs as a group of diseases that share involvement of the epidural space, adjacent dura mater, and bony structures. They adopted this definition for the classification of a spinal DAVF and an intracranial DAVF, according to the evolution and embryologic development of the venous drainage of the central nervous system and surrounding structures, such as vertebrae, skull base, and calvaria. According to this study, the dura and surrounding bone were closely related, and the DAVF could involve 1 of 2 compartments or both, though its etiology was uncertain.

Anatomically, the meningeal artery also supplies the adjacent bony structure, and the dura can share the venous drainage with the adjacent bony structure.¹⁵ In intraosseous DAVFs, the fistula is seen between the meningeal arteries and intraosseous diploic veins or the transosseous emissary veins, such as the anterior condylar vein; and intraosseous DAVFs have a clinical manifestation and natural course of venous drainage pattern similar to that of the classic DAVFs.^6,11 It would be more suitable to define an intracranial DAVF as an abnormal arteriovenous connection between the meningeal artery and vein or sinus or both within the dura or skull or both, for the inclusion of an intraosseous DAVF. Therefore, we consider that “intraosseous DAVF” is the proper and descriptive term and is a subtype of an intracranial DAVF in which the fistula is predominantly located at the intraosseous compartment.

There have been several reports of intraosseous DAVFs described as hypoglossal canal DAVFs and anterior or posterior condylar vein DAVFs.^9,10,12 These lesions could possibly be intraosseous DAVFs, but not always. Ernst et al⁹ described 3 cases of DAVFs that involved the anterior condylar vein within the hypoglossal canal. These cases seemed to be similar to intraosseous DAVFs because the lesions showed the presence of an intraosseous venous pouch adjacent to the hypoglossal canal and nidus within the bone on MR imaging and MRA source images. Tanoue et al¹¹ also described 2 similar cases in which the anterior condylar vein was involved. The first lesion involved the intracranial portion of the anterior condylar vein with reflux into the perimedullary vein and showed congestive myelopathy in the upper cervical spinal cord. It had no intraosseous component of a fistula. However, the second case involved the anterior condylar vein within the hypoglossal canal with an intraosseous venous pouch, and the lesion was treated completely with endovascular embolization via the transvenous approach. Recently, Kiyosue et al¹⁰ reported 1 case of a DAVF located at the posterior condylar canal. They also showed the presence of an intraosseous venous pouch adjacent to the posterior condylar canal, which was confirmed on posttreatment CT images. The 2 veins were transosseous emissary veins in the posterior cranial fossa. Therefore, we thought that these veins could be a route for venous drainage of any DAVFs involving the adjacent dural wall or an intraosseous DAVF.

In this report, we have described 2 fistulas that were located within the upper clivus and petrous apex. In these areas, though there were no specific nominated venous structures, it is known that transosseous emissary veins are abundant and complex in the skull base,^16,17 and it could be inferred that an intraosseous DAVF could occur in these areas related to the transosseous emissary vein.

A dilated venous pouch within the bone of an intraosseous DAVF was manifest as an osteolytic lesion on CT images, and signal-intensity enhancement within the bone was seen on TOF-MRA source images.³ For a classic DAVF, the venous structure could be stenotic or dilated due to an arteriovenous shunt.¹⁸ A dilated venous pouch could also be a secondary change from a fistula; however, because the shunt and related venous structure in the intraosseous DAVF are located within the bone, a dilated venous pouch within the bone could be an indirect sign on the CT or MR images.

Chen et al³ described the MR imaging findings of 2 patients with intraosseous DAVFs. For both patients, the nidus was located at the clivus. MR imaging and MRA source images showed the presence of an intraosseous venous pouch within the clivus. Additionally, the diploic space was well-enhanced on a postcontrast T1-weighted image, which is suggestive of intradiploic venous hypertension caused by an intraosseous DAVF. CT can help demonstrate the presence of the osteolytic portion secondary to the dilated venous pouch before treatment. The cases in the present study were similar to previously reported cases in which the fistula was located within the bone and an intraosseous venous pouch was also noted on CT angiography or MRA source images. We could demonstrate the intraosseous lesions in 2 patients on coronal source images of 3D rotational angiography, which are considered to provide the most accurate diagnostic information for the identification of intraosseous DAVFs by showing enhanced fine vascular structures and bone changes together (Fig 1E).

Intraosseous DAVFs in the posterior fossa can be treated by surgical resection, endovascular occlusion via the transarterial or transvenous route, or radiation or a combined technique. Surgical resection for a posterior fossa DAVF achieved curative results in several reports, but surgery was usually selected as a secondary choice after endovascular treatment because of the risk.^2,4,8

In selected cases, transarterial embolization of a DAVF in other locations could be curative,¹² but in the case of an intraosseous DAVF, most of the fistulas recurred after transarterial embolization.^3,8 The ascending pharyngeal artery (APA) was the main feeder for the intraosseous DAVFs in the previous reports and in the present cases. The APA not only supplied the DAVF but also supplied the lower cranial nerves such as the glossopharyngeal, vagus, and hypoglossal nerves.¹⁵ Transarterial embolization of the APA could produce a risk of lower cranial nerve palsy.⁹ Therefore, transarterial embolization of the DAVF might be a palliative option for symptomatic relief when a curative transvenous embolization is not possible technically.

Transvenous embolization of intraosseous DAVFs could be curative as ascertained in several studies and in the present cases.^9–12 We thought that it was very important to define the fistula focus as manifest by the dilated venous pouch within the bone. In cases with a lesion involving the hypoglossal canal, contralateral external carotid artery, or common carotid artery angiography could be helpful for localization of the lesion.^9,10 Source images of 3D rotational angiography could provide more accurate information than other imaging techniques. We were able to achieve complete occlusion of the DAVFs in all of the patients without any complications after embolization of the dilated venous pouch. Although the use of transvenous embolization would be safe, it could also cause complications. There was 1 case reported of a hypoglossal canal DAVF complicated by permanent hypoglossal nerve palsy after transvenous embolization in the dilated venous pouch.¹² Because the hypoglossal canal is a tubular canal with limited space, a packed coil mass within the canal could produce a mass effect on the hypoglossal nerve and cause nerve palsy.

Conclusions

The strategy and method of the treatment of intraosseous DAVFs is not different from those in classic DAVFs. Despite our limited experience, we can conclude that transvenous embolization, accurately targeted for the dilated venous pouch in an intraosseous DAVF, can be a safe and curative method, and a good clinical outcome can be expected immediately or during the follow-up period. For curative treatment, it is very important to analyze the angiographic architecture correctly. It would be helpful to determine if the intraosseous dilated venous pouch could be a target lesion; then it can be correctly localized by the use of coronal source images of 3D rotational angiography.