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Objective To investigate color Doppler flow imaging (CDFI)and transcranial color-coded sonography (TCCS)for detection and evaluation of severe stenosis of intracranial vertebral artery (IVA) before and after stenting,as well as the hemodynamic changes of restenosis and their clinical value. Methods A total of 102 patients with severe stenosis of IVA confirmed by CDFI plus TCCS and DSA from November 2011 to November 2013 were analyzed retrospectively. Extra- and intracranial segments peak systolic velocity (PSV),end-diastolic velocity (EDV),IVA pulsatility index (PI),extracranial resistance index (RI),tube diameter,spectrum morphology,and hemodynamic parameters before stenting and 1 week, 3,6 and 12 months after stenting were compared. According to the results of TCCS,they were further divided into either a restnosis group (n=16 )or a non-restnosis group (n=86 ). Results (1 )The results of TCCS detection showed:PSV,EDV,and PI of the stenotic segments were improved significantly at 1 week after stenting,they were 109 ± 40 cm/s vs. 258 ± 63 cm/s,47 ± 18 cm/s vs. 132 ± 45 cm/s,0. 91 ± 0. 15 vs. 0.75 ± 0. 18,respectively. There were significant differences (all P0. 05). (2)The results of CDFI showed:PSV and EDV of the ipsilateral extracranial segment were improved significantly after procedure compare with those before procedure, they were 64 ± 15 cm/s vs. 51 ± 15 cm/s and 24 ± 6 cm/s vs. 19 ± 7 cm/s (all P<0. 05). The RI value and vertebral artery diameter of the extracranial segment were improved gradually,and they reached the peak at 12 months after procedure (0. 61 ± 0. 07 vs. 0. 63 ± 0. 12,P=0. 038;3. 6 ± 0. 4 mm vs. 3. 4 ± 0.5 mm,P=0. 009). Conclusion CDFI in combination with TCCS can objectively evaluate the extra-and intracranial hemodynamic changes before and after IVA stenting,and provide reference information for the effectiveness of stenting and the imaging evaluation of restenosis.
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Objective To investigate the criteria of hemodynamic parameters for diagnosis of intracranial segment vertebral artery stenosis with transcranial color-coded sonography (TCCS ). Methods A total of 622 outpatients or inpatients with suspected posterior circulation ischemia were enrolled retrospectively,from which 216 patients were selected with TCCS,color Doppler flow imaging (CDFI)screen,and digital subtraction angiography (DSA)examination,including 33 patients (15. 3%) had normal intracranial vertebral arteries,the stenosis rates<50% were 45 cases (20. 8%),50%-69%were 44 cases (20. 4%),and 70%-99% were 94 cases (43. 5%). The mean velocity (MV)of intracranial segment,the ratios SPRP (PSV1/PSV2 ),SPRE (EDV1/EDV2 )of the systolic and end diastolic flow velocity between the intracranial segment and the intervertebral space segment were calculated respectively by detecting the intracranial segment of vertebral artery,the intervertebral space segment peak systolic velocity (PSV1 ,PSV2 )and end diastolic velocity (EDV2 ,EDV1 ). The DSA findings were used as the criteria,the area under the receiver operating characteristic (ROC ) curve was calculated and the optimal cut-off points were obtained. Results The optimal cut-off points of TCCS diagnosis of intracranial vertebral artery stenosis were as follows:the parameter standards of stenosis rate <50% were 110 cm/s≤PSV1≤145 cm/s and 65 cm/s≤MV≤85 cm/s,the parameter standards of stenosis rate 50%-69%were 145 cm/s≤PSV1≤190 cm/s and 85 cm/s≤MV≤115 cm/s,and the parameter standards of stenosis rate 70%-99% were PSV1≥190 cm/s and MV≥115 cm/s. Conclusion TCCS may effectively evaluate the hemodynamic changes of intracranial vertebral artery stenosis and provide reference for the ultrasound evaluation criteria of intracranial vertebral artery stenosis.
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Objective To analyze the correlations of vascular structure, hemodynamic changes and surgical recanalization of carotid endarterectomy ( CEA) for the treatment of subtotal or complete occlusion of carotid artery. Methods A total of 107 patients with carotid artery occlusive disease diagnosed at Beijing Xuanwu Hospital,Capital Medical University received CEA therapy from January 2005 to January 2014 and were enrolled retrospectively. According to the findings of introperative ultrasound,they were divided into either a recanalization group (n=86) or a non-recanalization group (n=21). Preoperative and intraoperative carotid artery diameter and blood flow velocity were compared and analyzed with carotid ultrasonography. Intraoperative detected vascular abnormalities, residual vascular stenosis rate, blood flow velocity and pulsatility index of the ipsilateral middle cerebral artery ( MCA) were documented. Results (1) The peak systolic velocity (PSV) (82 ± 32 cm/s and 60 ± 17 cm/s),mean velocity (MV) (50 ± 19 cm/s and 42 ±13cm/s),and pulsatility index (PI) (0. 97 ± 0. 25 and 0. 67 ± 0. 14) on the ipsilateral MCA in patients of carotid artery recanalization before and after procedure were significantly higher than those during the procedure. There were significant differences (all P=0. 000). In patients failed to recanalize,the intraoperative and preoperative PSV,EDV,and MV of MCA were 46 ± 20 cm/s and. 63 ± 21 cm/s,24 ± 13 cm/s and 34 ± 12 cm/s, and 32 ± 16 cm/s and 44 ± 15 cm/s,respectively. They were reduced more significantly during the procedure than those after procedure. There were significant differences ( all P=0. 000 ) . But there was no significant difference in PI (0. 70 ± 0. 18 and 0. 67 ± 0. 15) compared with that before procedure (P=0. 317). (2) The diseased vascular diameter of the recanalization group was significantly widened (0. 6 ± 0. 4 mm vs. 3. 4 ± 0. 9 mm,P=0. 000) compared with before procedure. The overall recanalization rate was 80. 4% (86/107). Intraoperative ultrasound revealed that 13 patients had mild abnormal vascular structures among the recanalized patients. The non-recanalized patients had significantly abnormal vascular structure. Conclusion Intraoperative carotid ultrasound in combination with transcranial Doppler (TCD) for monitoring cerebral blood flow may effectively identify the carotid structure and the degree of cerebral hemodynamic improvement,and timely guide the secondary repair.
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Objective Using transcranial Doppler (TCD) to evaluate the effect of selective shunt (SS) during carotid endarterectomy (CEA). Methods TCD was used for intraoperative bilateral middle cerebral artery (MCA) cerebral blood flow continuous monitoring in 169 patients with carotid stenosis treated with CEA. The patients were divided into shunt (n =32)and non-shunt (n = 137) groups according to whether they performed shunt or not. The open approaches of anterior collateral circulation were recorded. The peak systolic velocity (PSV),mean velocity (MV), pulsatility index (PI), and ratio of MV in bilateral MCA were compared after anesthesia, before and after carotid artery occlusion, before and after shunt, and after carotid artery open. Results MV before carotid artery occlusion in the shunt and non-shunt groups were 34.73 ± 13.54 cm/sand 35.32 ± 13.18 cm/s, respectively, and there was no significant difference (P = 0. 825). MV in the shunt group after carotid artery occlusion was significantly decreased in the non-shunt group (P =0. 000). The mean decline rate of MCA MV was 69.34% ± 20. 93%, and it was decreased more significantly than that in the non-shunt group (P=0. 000). The decline rate of MCA MV was increased significantly after shunt operation, the average increase was 35.68 ± 16.69 cm/s (P=0. 000). Conclusions TCD can objectively evaluate the hemodynamic changes before and after shunt operation.