Usefulness of MR Imaging for the Assessment of Nonophthalmic Paraclinoid Aneurysms

Patients and Selection of Aneurysms

We evaluated PMP in 14 consecutive female patients (median age, 45 ± 14 years) harboring 17 asymptomatic PA between June 2002 and June 2005. PA were defined as aneurysms arising from the C4, C5, or C6 segments according to the Bouthillier classification of the ICA segments.¹⁰ We studied carotid cave projecting aneurysms (arising from the medial wall of the ICA, most often at the level of the origin of the superior hypophyseal artery), high-located, cavernous, subclinoid, and low-located posterior carotid aneurysms. Giant aneurysms and purely anterior (superior or “carotid-ophthalmic”) aneurysms were excluded.

Angiographic Technique and Classification

We performed conventional angiograms on an Integris Allura V5000 (Philips Medical Systems, Best, the Netherlands) using the PROPELLER rotation technique.¹¹ We then performed postprocessing of dynamic angiographic data, including volume rendering, using the Integris workstation (Philips Medical Systems).

The orientation of the aneurysmal neck and sac was determined according to the angiographic classification described by De Jesus et al.² as follows: we distinguished medial or lateral projections on the anterior view and anterior or posterior projections on the lateral view. To locate on DSA the aneurysmal neck and sac in comparison with the roof of the cavernous sinus and to ensure the reproducibility of the method, we chose the limit represented by the horizontal line passing through the origin of the ophthalmic artery on the lateral and anterior views. We classified the aneurysmal neck and sac as supracavernous, above the ophthalmic line; transitional, crossing the ophthalmic line; and intracavernous, beneath the ophthalmic line. Cases with an obvious intracavernous origin of the ophthalmic artery were excluded.

Paraclinoid MR Protocol

Brain MR imaging was performed on a 1.5T MR system (Vision; Siemens, Erlangen, Germany). A turbo spin-echo T2-weighted sequence (TR, 5000 ms; TE, 120 ms; NEX, 2; contiguous section thickness, 2.0 mm; FOV, 32 cm; matrix, 512 × 512) was performed. For each aneurysm, we obtained sections in 2 planes: a coronal plane perpendicular to the diaphragma sellae (so-called diaphragmatic plane) and a sagittal oblique plane, strictly anteroposterior passing through the axis of the carotid siphon (so-called carotid plane).

In preliminary studies, we defined the reference points, correlation lines, and angles that correlated with the limits of the distal dural ring plane in both cutting planes.^8,9 We used 40 paraclinoid regions (dissected from 20 formalin-fixed human cadaveric heads) to correlate the MR data with a cadaveric model. In our study, the PMP angles allowed us to accurately locate the distal dural ring plane in the diaphragmatic and carotid planes in 70% and 80% of the cases, respectively.

In our study, we propose a simple and practical method allowing the use of the PMP protocol in clinical practice (Fig 1). The distal dural ring plane is a curved plane passing through 4 radiologic reference points: the diaphragmatic point (in the diaphragmatic plane) at the borderline between the diaphragma sellae and the roof of the cavernous sinus; the clinoid point (in the diaphragmatic plane) at the medial ridge of the superior surface of the anterior clinoid process; the anterior and posterior CSF notches extremity (in the carotid plane); and indirect markers formed by CSF cisterns around the ICA, respectively, between the optic nerve or the roof of the cavernous sinus and the anterior or posterior aspects of the ICA. The inferior limit of the distal dural ring plane is estimated in each cutting plane by the intersection angle formed by the lines passing through these 4 points. Rapid and simple drawing of those 4 lines can be achieved as follows: diaphragmatic line (through the diaphragmatic point); clinoid line (through the clinoid point); and roof line (through the posterior CSF notch extremity), respectively, tangential to the diaphragma sellae, the inner dural surface of the anterior clinoid process and the cavernous sinus roof, and optic line (through the anterior CSF notch extremity) perpendicular to the optic nerve at the level of its penetrating point in the optic canal.

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Fig 1.

Paraclinoid MR protocol in a control subject showing the 4 reference points. The 4 lines and their angles of intersection correlated with the limits of the distal dural ring plane in each cutting plane. A, B, C, Paraclinoid region in the diaphragmatic plane. D, E, F, Paraclinoid region in the carotid plane. DP indicates diaphragmatic point; CP, clinoid point; DL, diaphragmatic line; CL, clinoid line, ACNE, anterior CSF notch extremity; PCNE, posterior CSF notch extremity; OL, optic line; RL, roof line, DDRP, distal dural ring plane (dotted curve).

We determined the orientation of the aneurysmal neck and sac compared with the ICA by distinguishing medial or lateral projections in the diaphragmatic plane, and anterior or posterior projections in the carotid plane.

The MR positioning of the aneurysmal neck and sac compared with the roof of the cavernous sinus was based on their relationship with each intersection angle in both planes as follows: supracavernous (above both intersection angles), transitional (crossing 1 or both in-tersection angles), and intracavernous (beneath both intersection angles).

Treatment of the Aneurysms

All cases of asymptomatic aneurysms at our institution are managed by a multidisciplinary neurovascular team. For PA, we took into account principally the location of the aneurysmal sac, the history of a previous SAH, and the ages of the patients. When the sac was intracavernous, we chose conservative management. For a transitional or supracavernous sac, embolization or surgery was usually required because of the risk of hemorrhage. An exception was made for some of the transitional or supracavernous aneurysms that were too small (<1–2 mm) for endovascular or surgical treatment, or for those aneurysms associated with carotid dysplasia.

Descriptive Analysis

Epidemiologic data for each patient were documented. Angiograms were reviewed on films from anterior, lateral, and 3D views by an experienced neuroradiologist specialized in endovascular treatment of the cerebral aneurysms (X.L.). MR imaging data were reviewed independently by 2 investigators (L.T., J.-Y.G.). We measured the ratio of the neck and sac of each aneurysm and assessed the projection of the aneurysmal neck and sac around the ICA (anterior, posterior, medial, lateral) and their locations regarding the roof of the cavernous sinus. Therapeutic modalities of the management for each patient were recorded. For patients in whom an operation was performed, we took operative field shots to make radiologic-surgical correlations.

Statistical Analysis

The angiographic and MR imaging results in terms of measurement of the sac and neck, and the sac-to-neck ratio were compared with the t test. The intrinsic validity of the PMP was evaluated with aneurysmal measurement (sac, neck, and sac-to-neck ratio) with the t test and interobserver agreement for the aneurysmal projection around the ICA and location around the roof of the cavernous sinus with the κ coefficient. The agreement was considered as low, moderate, good, or excellent according to the respective κ coefficient values: ≤0.40, 0.41–0.60, 0.61–0.80, ≥0.81. A P value <.05 was regarded as significant.

General Data

Fourteen patients (17 PA) were enrolled in the study. After angiography, most patients were found to have at least 1 additional vascular disease: 10 patients with at least 1 associated aneurysm (1 dysplasia) and 1 patient each with contralateral Moyamoya disease and contralateral arteriovenous malformation. Seventeen associated aneurysms were found: carotid-ophthalmic (5), posterior carotid (5), PA (3), basilar (2), middle cerebral artery (1), and proximal ICA (1). Ten PA were incidentally discovered, and 7 were diagnosed after SAH as a result of an associated vascular disease.

Angiographic Results

We performed DSA with 3D-reconstructions on most of the PA (14/17). The mean sizes of the necks and sacs were 3.1 ± 1 mm and 5.9 ± 4 mm, respectively. The mean sac-to-neck ratio was 1.9 ± 0.9. Seven PA were located in the intracavernous position, 8 were transitional, and 2 were supracavernous.

MR Imaging Results

The mean sizes of the necks and sacs were 3.5 ± 1.3 to 1.4 mm and 6.2 to 6.3 ± 3.8 mm, respectively. The mean sac-to-neck ratio was 1.8 ± 0.7. Six PA were located in an intracavernous position, 7 were transitional, and 4 were supracavernous. No significant differences (P >.05) were found between the investigators for the measurement of the aneurysmal neck or sac. The interobserver agreement for the projections of the aneurysmal neck or sac (κ = 0.87:1) and for the location of PA around roof of the cavernous sinus (κ = 1) were “excellent.”

Treatment of the Aneurysms

Ten PA including 6 intracavernous and 4 transitional or supracavernous—but very small (<2 mm) or associated with severe intracranial arterial dysplasia—were managed conservatively. Six patients with PA underwent endovascular treatment because of the supracavernous (2 cases) and transitional (4 cases) locations of the sac in young patients or in patients with previous SAH. One patient underwent direct surgical treatment of PA.

Surgical Results

A young patient was operated on after failure of coil embolization for a supracavernous aneurysm, which was revealed by the rupture of an associated aneurysm (case 14). Another patient was operated on for a carotid-ophthalmic aneurysm (superior location) associated with an intracavernous PA (case 16). In both cases, the aneurysmal locations provided by the PMP were similar to the surgical findings. The first aneurysm was supracavernous and was clipped (Fig 2). The second was not seen after full dissection of the paraclinoid region down to the distal dural ring and was supposed to be intracavernous.

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Fig 2.

Radiologic-surgical correlation for a left superolateral paraclinoid aneurysm (case 14). A, DSA of the left ICA (lateral view) showing an aneurysm (arrows) interpreted as transitional with an intracavernous neck and a transitional sac. B, C, PMP in the diaphragmatic plane with an intersection angle showing a supracavernous location of the neck and the sac (DL indicates diaphragmatic line; CL, clinoid line). D, Operative findings confirming the supracavernous location of both neck and sac and showing, after anterior clinoidectomy and opening of the falciform ligament, the aneurysmal (arrowhead) relationship between the ICA and the optic nerve (ON).

Comparison between the PMP and DSA

No significant difference (P >.05) was found between DSA and the PMP for the measurement of the aneurysmal necks or sacs (Table). In 9 cases (2, 5, 7–9, 11–13, and 16), DSA and the PMP gave the same aneurysmal location (Figs 3, 4, and 5). Interpretations on DSA in cases 1, 3, and 6 were different from the PMP for the locations of the neck or sac. Interpretations on DSA in cases 4, 10, 14, 15, and 17 were different from the PMP for the locations of the neck and sac (Fig 2).

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Fig 3.

Comparison between angiogram and PMP for the location of case 2 (arrows). Both examinations show an intracavernous aneurysm (neck and sac intracavernous). A, DSA of the left ICA in the lateral view. B, 3D-DSA of the left ICA in the anterior view. C, PMP in the carotid plane (OL indicates optic line; RL, roof line). D, PMP in the diaphragmatic plane (DL indicates diaphragmatic line; CL, clinoid line).

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Fig 4.

Comparison between angiogram and the PMP for the location of case 13 (arrows). Both examinations show a transitional aneurysm (neck intracavernous and sac transitional). The PMP depicts a widest supracavernous portion than it is suspected on initial DSA. A, DSA of the left ICA in the lateral view. B, 3D-DSA of the left ICA in the anterior view. C, PMP in the carotid plane (OL indicates optic line; RL, roof line). D, PMP in the diaphragmatic plane (DL indicates diaphragmatic line; CL, clinoid line).

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Fig 5.

Comparison between angiogram and PMP for the location of case 11 (arrows). Both examinations show a transitional aneurysm (neck supracavernous and sac transitional). The PMP depicts a wider supracavernous portion than is suspected on initial DSA. A, DSA of the left ICA in the lateral view. B, DSA of the left ICA in the anterior view. C, PMP in the carotid plane (OL indicates optic line; RL, roof line). D, PMP in the diaphragmatic plane (DL indicates diaphragmatic line; CL, clinoid line).

Review of the Literature

The origin of the ophthalmic artery is commonly used as the angiographic limit between the intracavernous and supracavernous ICA.⁴ Because of its interindividual variability,^4,12–16 this reliable marker may sometimes fail to locate this junction precisely, anatomically represented by the distal dural ring. The ophthalmic artery may arise from the ICA in the extradural space, most often far below the distal dural ring (artery of the foramen rotundum, inferolateral trunk) and is easily recognized as anomalous and unreliable but rarely near the distal dural ring (clinoid space, interdural location). Most ophthalmic arteries originate in the intradural space, but the distance between the origin and the distal dural ring may vary in 24% to 50% of cases. This variability led some to design techniques of radiographic correlation using some of the bony structures of the skull base on lateral and anterior nonsubtracted angiograms: the base of the anterior clinoid process,¹⁷ the superior surface of the anterior clinoid process and the tuberculum sellae¹⁸ or the planum sphenoidale, and lines of the tuberculum sellae.¹⁶ Recently, 3D reconstructions from CT scans,¹⁹ CT angiograms,²⁰ or contrast medium-enhanced tomographic cisternograms²¹ have been used. These radiologic procedures were respectively based on the visualization of the strut of the optic canal, identification of a surface concavity at the level of the distal dural ring, and CSF cisterns contrast around the ICA. Although effective, these protocols did not take into account the complexity of the extravascular anatomy of the paraclinoid region, particularly of the radiotransparent dural folds of the walls of the cavernous sinus. An indirect approach and interindividual radiologic variability were the major limitations of the above techniques.

Value and Limitations of the PMP

Reproducibility and accuracy of the PMP was proved in preliminary anatomoradiologic studies.^8,9 In this clinical study, the MR technique allowed the identification and the precise positioning of the PA detected with DSA for all patients. The results confirmed the interobserver reproducibility for the aneurysmal measurement and location, and the reliability of the aneurysmal dimensions obtained with the PMP. In 2 cases, the results of the PMP were confirmed by surgical exploration of the paraclinoid region. Compared with DSA, the PMP provides a global view of the paraclinoid anatomy and direct visualization of the radiotransparent dural folds comprising the roof of the cavernous sinus. Therefore, the PMP could increase the quality of the overall radiologic analysis by providing direct visualization of the aneurysm and a reliable evaluation of the size of the intracavernous and supracavernous portions of transitional aneurysms.

Discordance between interpretations of DSA and PMP were found in 8 cases. Differences were more frequent for medial or medial-posterior projecting PA (5/8) and for the location of the aneurysmal sacs (7/8). Improvement of the location of the aneurysmal sac around the roof of the cavernous sinus is of importance, considering that it is the most usual site of rupture. In our study, we had surgical correlations in 2 cases only, so the discordances between DSA and the PMP should be carefully analyzed. Furthermore, the arbitrary choice of the horizontal line passing through the origin of the ophthalmic artery as the only angiographic limit between the intracavernous and extracavernous spaces could have led us to misinterpret some of the DSA. Some aneurysms could have been quoted in the wrong location. In those cases, the PMP technique has perhaps helped us only to clarify misinterpretations on DSA.

This PMP technique requires a short training period to become familiar with the MR imaging anatomy of the paraclinoid region. Therefore, a simplified protocol that could be applied in clinical practice by all neuroradiologists is proposed.

Potential Implications for the Management of PA

Advances in neuroradiologic techniques are responsible for the increased diagnosis of asymptomatic aneurysms. Furthermore, because of therapeutic implications, clinicians’ and patients’ demands for radiologic accuracy have grown. The location of PA compared with the roof of the cavernous sinus illustrates this situation perfectly. In the treatment decision making, the neurovascular team takes into account the benefit-to-risk ratio among 3 therapeutic options: conservative, endovascular, or surgical. The rates of morbidity and mortality related to endovascular and surgical treatment of asymptomatic aneurysms are, respectively, 1% and 4%^6,22 and 2.6% and 10.9%,^22,23 the surgical morbidity being slightly higher for PA.²⁴ The spontaneous risk of rupture of these aneurysms (sizes are approximately 6 mm and are located on the anterior circulation) varies between 0.05% and 0.5% per year, whether there is a previous history of SAH from an associated aneurysm (7/17 cases in this study).²⁵ In women with a mean age of 45 years and a life expectancy of approximately 84 years, the cumulative risk of rupture (conservative treatment) can reach 1.8% to 18% and is not so different from the risk of endovascular or surgical treatment, especially if there are individual risks of aneurysmal growth such as arterial hypertension, smoking, or a familial history of SAH or connective tissue disease.^6,26–28 The decision of curative treatment for PA relies on the certainty that they are supracavernous or transitional aneurysms (at risk of SAH).

In our own clinical experience, the PMP allowed us to differentiate among intracavernous, supracavernous, and transitional aneurysms more precisely and to adapt the therapeutic management to the aneurysmal location. Intracavernous aneurysmal sacs were conservatively managed, whereas supracavernous or transitional aneurysmal sacs were treated with endovascular or surgical intervention. Only very small or dysplastic supracavernous or transitional sacs were not treated. Overall, the association of DSA and PMP benefited the treatment decisions in 4 patients (cases 10, 14, 15, and 17).