Recovery of Ophthalmoplegia after Endovascular Treatment of Intracranial Aneurysms

Discussion

Several pathogenetic mechanisms have been described in the literature concerning third nerve paresis, such as direct compression by an enlarged aneurysmal sac within the suprasellar cistern,⁶ pulsatility inside the aneurysm,⁷ or an irritating effect of subarachnoid blood.⁸ Mydriasis can be caused by an ICA-PcomA aneurysm compressing the oculomotor nerve superomedially and, more specifically, the dorsomedially located iridoconstrictor fibers.⁹ Compression of the pain sensory afferent fibers, which are recruited from the ophthalmic division of the trigeminal nerve and which lie within the periphery of the oculomotor nerve, causes ipsilateral orbitofacial pain.¹⁰ Compressive lesions of the cavernous sinus may lead to localized oculomotor or abducens CN dysfunction and Horner syndrome.¹¹Evolution of ocular motor nerve (third, fourth, and sixth) paresis after endovascular therapy has been reported in the literature: Beyond sporadic reports with ONP resolution after coiling of PcomA aneurysms,¹² a literature review concerning series including ≥3 aneurysms revealed a mean rate of 46.6% complete recovery after endovascular treatment of 118 (55/118) aneurysms that caused ophthalmoplegia (Table 5).^7,9,13–21 Our results concerning endovascular treatment are very encouraging: In a mean follow-up of 19 months (range, 0.2–73 months), complete resolution of ocular motor nerve (third, fourth, and sixth) paresis occurred in 50% of our patients, whereas 40% recovered incompletely and only 10% showed no improvement.

These results seem to be in the upper range or, in some cases, superior to the results previously reported in endovascular series. It seems probable that coiling eliminates the pulsatility inside the aneurysm sac and, therefore, the “hammer effect” on the nerve. This mechanism offers the opportunity for the affected nerve to recover partially or completely in most of the cases treated endovascularly. Nevertheless, in patients with long-standing and severe third nerve paralysis, aberrant regeneration with misdirection of fibers in a noncoordinated way may occur, leading to poor clinical outcome. In contrast, complete recovery with good clinical outcome is quite common in isolated sixth or fourth nerve palsies because these nerves innervate only 1 muscle and the phenomenon of aberrant disorganized regeneration does not occur. In case of ruptured aneurysms, coiling protects additionally from further potential rebleeding and allows resorption of the subarachnoid blood, thus resolving gradually its irritating effect on the nerve. In this respect, endovascular coiling seems to be an alternative minimally invasive method to neurosurgical clipping.

The positive effect of early treatment on final ONP recovery has been shown in several studies concerning endovascular treatment of ophthalmoplegic aneurysms^7,9,13,15: Kazekawa et al¹³ demonstrated that the group with resolution or improvement of symptoms had a shorter duration of symptoms before coiling (P < .05). Mansour et al¹⁵ reported that symptoms resolved in 75% of patients presenting with them for <1 month, whereas the rate dropped to 33.3% in cases in which symptoms lasted for >4 weeks. Unlike these findings, in our study, the interval time between CNP and the intervention did not affect the degree of postintervention resolution of CNP. This finding was in accordance with previous series concerning coiling of aneurysms that caused ophthalmoplegia.^16,17

As reported in previous studies, aneurysm size had no predictive value concerning recovery of ophthalmoplegia after endovascular treatment.^13,16,18 Nevertheless in a series by Mansour et al,¹⁵ the complete resolution rate was 71.4% for aneurysms <15 mm and 50% for aneurysms >15 mm. According to our results, though smaller aneurysms (≤10 mm) showed a higher tendency for better CNP recovery, the difference in the outcome between sizes <10 mm and ≥10 mm was not statistically significant (Fig 1); thus, aneurysm size was not considered to have a predictive impact.

Although Mansour et al¹⁵ reported a 42.8% complete recovery rate of unruptured aneurysms treated endovascularly and a rate for ruptured aneurysms of 100%, Chen et al,¹⁸ who compared coiling versus clipping as a treatment of ONP aneurysms, demonstrated no effect of the presence of subarachnoid hemorrhage on recovery of ONP. In our study, more patients achieved a complete recovery of CNP in cases of unruptured aneurysms (6/18, 67%) than in cases of ruptured aneurysms (3/12, 25%); nevertheless, this tendency did not reach statistical significance.

Concerning the outcome of CNP after endovascular treatment according to location, Kim et al⁹ reported a higher tendency concerning CNP improvement or resolution for intradural than for extradural aneurysms, with a rate of 89% and 17%, respectively. This tendency could not be reproduced in our series. According to our results, as illustrated in Table 2, the highest tendency for complete CNP recovery occurred in aneurysms located in the posterior circulation (4/5, 80%), whereas the lowest tendency for complete resolution occurred in aneurysms located in the ICA-PcomA (3/10, 30%).

According to our results, the degree of initial CNP (ie, complete or partial) was the only parameter that affected significantly (P = .009) the recovery degree of nerve function after endovascular treatment in our patients: The percentage of complete CNP resolution was 68.4% (13/19 patients) after endovascular treatment in patients initially presenting with incomplete CNP, whereas complete recovery occurred in only 18.2% (2/11 patients) of those initially presenting with complete CNP (Fig 3). Figure 4 illustrates a case of a patient with a partial sixth nerve paresis for 2 months due to an unruptured cavernous aneurysm. The paresis recovered fully after endovascular treatment with stent-supported coiling. As previously reported in the literature, the degree of initial CNP plays a significant role in the final outcome either after endovascular or surgical treatment.

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Fig 4.

Unruptured cavernous aneurysm of the left ICA causing partial sixth cranial nerve paresis for 2 months. Anteroposterior (A and B, early and middle arterial phase) and lateral arteriograms (C and D, early and middle arterial phase) before intervention. Anteroposterior (E) and lateral arteriograms (F) after stent-supported coiling. The white arrows in the insert of the anteroposterior arteriogram (E) show the stent struts.

Mansour et al¹⁵ reported 100% resolution of symptoms after coiling in patients presenting initially with partial CNP and 50% resolution in patients presenting initially with complete CNP. Hanse et al¹⁶ showed that initial partial palsy of CN III was the only predictor of complete recovery at follow-up. In this series, 83.3% of patients who initially presented with incomplete palsy of CN III recovered completely, whereas only 20% of the patients initially presenting with complete palsy of CN III recovered completely. In a comparison study (coiling versus clipping for treatment of ophthalmoplegic aneurysms), Chen et al¹⁸ showed that the degree of oculomotor nerve paresis (ie, complete or partial) affected recovery of nerve function regardless of treatment method: Partial oculomotor nerve paresis promises better recovery after either clipping or coiling of a PcomA aneurysm.

Surgical treatment, by clipping the aneurysm neck, relieves the mass effect and offers adequate decompression of the nerve. In the literature, a mean rate of 44% complete recovery has been reported after surgical treatment of 339 (149/339) aneurysms that caused ophthalmoplegia (Table 6).^1,18,21,22 Most of the aneurysms were located in the PcomA, whereas only 1 was located in the posterior circulation. The time interval from onset of oculomotor nerve paresis to treatment seems to be of critical importance: In a review performed by Leivo et al,¹ the mean rate of 41% complete ONP recovery after clipping rose to 64% in patients undergoing surgery within 2 weeks, whereas the number diminished significantly in patients undergoing surgery later, within 14–30 days (30%) and after 1 month (14%). Leivo et al reported a mean rate of 57% complete ONP recovery in their own patients, which rose to 80% in patients undergoing surgery within 1 week. In another series by Yanaka et al,²² immediate surgical treatment (within 5 days from the onset of oculomotor palsy) offered the best rates for recovery of neural function. Although our study does not compare endovascular and surgical treatment of ophthalmoplegic aneurysms, our results (50% complete resolution of CNP and 40% incomplete recovery) seem to be comparable with, or in some cases superior to, surgical outcomes reported in the literature.

Considering the high degree of complete and partial CNP recovery in our study (90%) combined with a low permanent morbidity rate (6.6%), we conclude that coiling is an effective and safe method for the treatment of aneurysms presenting with ophthalmoplegia due to CNP.