Postoperative complication and clinical outcome
Hemorrhagic MMD has high rehemorrhage rates between 32% and 61%, usually leading to high mortality and disability.6–8, 11 The primary emphasis has been to reduce this with a potential revascularization surgery rather than conservative treatment. Recent studies identified that surgical revascularization can significantly reduce the rehemorrhage rates to 12–17% and improves the clinical neurological function as compared with conservative treatment in patients with hemorrhagic MMD.5,9,15,23 Although the optimal revascularization procedure among combined revascularization (CB), direct revascularization (DB) and indirect revascularization (IB) for hemorrhagic MMD is still controversial, most investigators believe that CB is superior to IB in preventing stroke recurrence, which was consistent with this study. This study also showed that the patients with mRS ≤ 2 points was significantly greater in the CB group than in the IB group (P = .009). Therefore, compared with IB, CB can better reduce the incidence of recurrent stroke, avoid secondary damage to neurological function caused by rebleeding, and obtain better clinical prognosis. Since the electrocoagulation was rarely used during the operation as well as the temporal muscle and skin had rich blood supply, the postoperative delayed wound healing was no significantly different between the two groups (P = .309).
At present, most studies have emphasized on the clinical prognosis, stroke recurrence and related risk factors, while few studies focus on why different revascularization procedures often company with various neurofunctional prognosis, and whether the diverse impacts on neovascularization and hemodynamics play a role. Therefore, we conduct this study to investigate the postoperative collateral circulation formation and cerebral hemodynamics between CB and IB, and to provide a foundation for improving the revascularization procedures and a guidance for utilizing the vasoactive and angiogenic medications.
Postoperative collateral circulation
Suzuki stage, a time-oriented classification, has been applied wildly to evaluate the progression of MMD, but it can’t completely take the individualized level of collateral circulation into account.24–26 Thus, we adopted the novel classification criteria, proposed by Liu et al. (Table 1, Fig. 1) to assess the preoperative collateral circulation status in order to ensure the preoperative homogeneity between the two groups.18
In this study, we found that CB group had better neovascularization than IB group (P = .03). It may be that the neovascularization of CB consisted of directed STA-MCA bypass vessels and sticking vessels including the meningeal arteries and deep temporal artery, etc, while the IB group only possessed the sticking vessels. Previous studies thought that DB can provide immediately the cerebral blood flow and promote neoangiogenesis, while IB will take at least 3 months to induce neovascularization with increased cerebral perfusion, but the long-term and stable effect on neovascularization should not be neglected.14–15, 17, 25, 27 Although Park SE et al. and Zhao Y et al. believed that the role of indirect revascularization in promoting neovascularization was limited, a large proportion (52.4%) of patients in our study obtained good neovascularization in the IB group.15,28 We hypothesis that the younger age of our patients and different procedures of IB might play a role. Peicong Ge et al. believed that the younger the patients at the operation, the better postoperative collateral formation.29 In addition, in their studies, encephaloduroarteriosynangiosis (EDAS) and encephalodurosynangiosis (EDS) procedures was performed, while we applied encephaloduroarteriomyosynangiosis (EDAMS) procedure, in which temporal muscle flap with deep temporal artery might be superior to EDS or EDAS in the ingrowth of new vessels. This is also consistent with the study of Zhao J et al. that the encephaloduromyosynangiosis (EDMS) operation can provide lasting revascularization.14 Meanwhile, the improvement of AchA-PcoA dilation or extension was significantly obvious in the CB group than in the IB group (P = .011). We speculated that both the directed STA-MCA anastomosis and sticking vessels in CB group could reduce the hemodynamic stress of the terminal internal carotid artery and its abnormal branches in short-term or long-term, and improve the extension and dilation of AchA-PcoA, which was also the reason that the rehemorrhage rate is lower than the IB group.10,11,30 However, the regression of moyamoya vessels occurred in both CB and IB group, but there was no statistical significance between the two groups (P = .76). We speculated that it might been caused by the not enough sample size and follow-up duration.
Postoperative improvement of hemodynamics
The postoperative rCBF, rCBV, MTT and rTTP were all significantly improved as compared with those before revascularization surgery in the CB group (all P < .001), which was consistent with the report that the revascularization increased substantive perfusion.31 Simultaneously, the postoperative rCBF, rCBV and MTT were also improved after indirect bypass surgery, we inferred that the ingrowth of sticking vessels might also increase the substantive cerebral perfusion in some extent. Although the rTTP was also improved slightly in the IB group, there was no statistical difference in the rTTP as compared with that before revascularization (P = .067). This may be that rTTP reflects the time that the cerebral blood flow reaches a peak rather than the amount of perfusion, and it depends on the diameter of superior vascular lumen, and its delay can’t reflect hypoperfusion sufficiently.32 Although Wintermark M et al. showed that rTTP was quite sensitive to the changes of perfusion in the acute period of infarction, the follow-up time in this study was 16.5 ± 8.7 months, a relatively long time.33 Thus, we speculated that the phenomenon was caused by the small new vessels’ lumen and small blood flow. In addition, the CB group’s postoperative rCBF was significantly higher than the IB group (P < .001). We speculated that CB group had better neovascularization receiving dual blood supplies from STA-MCA anatomies and sticking vessels, which were more conducive to improving cerebrovascular autonomic regulation, rapidly increasing parenchymal cerebral perfusion and significantly improving the rCBF.
In summary, combined ameliorating hemodynamic stress in short-term and promoting the neoangiogenesis in long-term, the CB group can perform better neovascularization and improvement of rCBF and AchA-PcoA extension/expansion, which prevented the secondary damage to the neurologic function from recurrent stroke events and got a more satisfactory prognosis. Thus, we inferred that the STA-MCA combined EDAMS is the optimal procedure for hemorrhagic MMD, maybe, and the use of vasoactive and angiogenic medicines locally or systemically is likely to enhance this efficacy, which is well-deserved to be further studied.
Limitations:
This is a single center and retrospective study. The follow-up time is no long enough. There may exist selection bias in choosing CB or IB revascularization procedure, and the sample size was not large enough with only 68 hemispheres in 37 patients. We failed to consider the reciprocal effects between 2 hemispheres, which remains to be further studied. Although the collateral circulation and hemodynamics in the CB and IB groups were assessed in this study, the factors related to the collateral circulation and hemodynamics were not further analyzed.