Objective To observe the clinical characteristics and therapeutic effects of carotid artery stenosisrelated ocular ischemic appearance(OIA).Methods The clinical data of 210 patients of carotid artery stenosis (81 of them with OIA) were retrospectively reviewed. They were diagnosed by color doppler image(CDI)or digital subtraction angiography (DSA),and had undergone medicine,carotid artery stenting (CAS)and carotid endarterectomy (CEA). Of 81 patients with OIA,49 patients (60.49%) with OIA only, 32 patients(39.51%)with ocular ischemic disease (OID).24/32 OID patients received ophthalmic treatment such as retinal laser photocoagulation and anti glaucoma therapy (drugs and cyclocryotherapy). Results The ocular manifestations of 81 OIA patients included transient amaurosis in 38 cases (47.14%),flash before the eye in 30 cases (36.67%), periorbital swelling and pain in 28 cases (34.57%), diplopia in 11 cases (13.58%) and vision loss in 9 cases (11.11%). The ocular manifestations of 32 OID patients included ischemic optic neuropathy in 9 cases (28.13%), ocular ischemic syndrome in 6 cases (18.75%), central or branch retinal artery occlusion in 6 cases (18.75%), retinal hemorrhage in 5 patients (15.62%),extraocular muscle paralysis in 4 patients (12.50%) and neovascular glaucoma in 2 patients (6.25%). The higher the degree of carotid stenosis,the higher incidence of ocular ischemic disease,there was highly positive correlation between each other (R=0.837, P<0.05).The total effective rate of carotid artery stenting and carotid endarterectomy was significantly higher than drug treatment alone (t=2.73, 3.14; P<0.01). Conclusion The ocular manifestations of carotid stenosis related ocular ischemic appearance can be transient amaurosis, eyes flashing,eye redness,periorbital pain, diplopia and decreased visual acuity.The ocular manifestations of carotid stenosisrelated ocular ischemic disease can be ischemic optic neuropathy, ocular ischemic symptoms, central or branch retinal artery occlusion and neovascular Carotid artery stenting and carotid endarterectomy are more effective than drug treatment alone for those patients.
More and more people suffered from the car otid artery obstruction. It is reported that it's around 69% of these patients the first clinical manifes tation of carotid occlusive disease is the ocular ischemic syndrome. Owing to th e most symptoms of the ocular ischemic syndrome are very obscure, so there are a lways overlook or made a misdiagnosis of this entity in clinical. Fundus fluores cein angiography (FFA) is the best procedure to find this entity. We should pay close attention to notice the early phase of FFA. It is the most specific FFA si gn in ocular ischemic syndrome, and it is a distinctly unusual finding to find t he ocular ischemic syndrome. (Chin J Ocul Fundus Dis, 2008, 24: 79-81)
ObjectiveTo observe ocular ischemic appearance (OIA) associated with carotid artery stenosis and its effects on the hemodynamics of central retinal artery (CRA) and ophthalmic artery (OA). MethodsA total of 30 normal persons and 60 patients with carotid artery stenosis diagnosed by color Doppler flow imaging (CDFI) and digital subtraction angiography (DSA) were enrolled in this prospective study.Sixty patients were randomly divided into 2 groups:30 patients with the carotid artery stenosis degree < 60% and 30 cases with the carotid artery stenosis degree≥60%. Thirty normal persons were enrolled in the normal control group. All patients underwent a comprehensive eye examination to determine if OIA exists. The Doppler spectral patterns of CRA and OA were observed by CDFI. The peak systolic velocity (PSV), end diastolic velocity (EDV), blood vessel diameter (BVD) and resistance index (RI) of CRA and OA were measured. ResultsIn the group of the carotid artery stenosis degree≥60%, 24/30 patients (80.0%) had the ophthalmic symptoms and 9/30 patients (30.0%) had ophthalmic signs. In the group of the carotid artery stenosis degree < 60%, 9/30 patients (30.0%) had the ophthalmic symptoms and 3/30 patients (10.0%) had ophthalmic signs. For patients with≥60% stenosis, CDFI revealed a bread-like waveform of CRA, and single peak of OA instead of the typical 3-peak/2-notch waveform. For patients with < 60% stenosis, CDFI revealed a normal pattern of CRA and OA (3-peak/2-notch). The PSV(t=5.255, P=0.007) and EDV(t=4.949, P=0.005) of CRA in the stenosis≥60% group were statistically decreased compared to the normal control group, but the BVD(t=0.457, P > 0.05)and RI(t=0.213, P > 0.05)were normal. The PSV, EDV, BVD and RI of CRA in the stenosis < 60% group were normal(P > 0.05). The PSV(t=4.457, P=0.010)and EDV(t=4.588, P=0.009)of CRA in the stenosis≥60% group were statistically decreased compared to the stenosis < 60% group, but the BVD and RI were the same between these 2 groups. ConclusionPatients with carotid stenosis≥60% had a higher OIA incidence, reduced PSV, EDV of their CRA, while had no significant changes of OA hemodynamics.
ObjectiveTo observe the effects of carotid artery stenting (CAS) on ophthalmic artery blood flow in patients with ischemic ophthalmopathy (IOP).MethodsA prospective case-control study. Sixty IOP patients (60 eyes) who met inclusive criteria for CAS were enrolled in this study. There was 50% stenosis of internal carotid artery on one side at least confirmed by color doppler flow imaging (CDFI). Among 60 eyes, there were 3 eyes with central retinal artery occlusion, 15 eyes with retinal vein occlusion, 37 eyes with ischemic optic neuropathy, 5 eyes with ocular ischemia syndrome. The patients were randomly divided into CAS group (32 eyes of 32 patients) and medicine therapy group (28 eyes of 28 patients). The difference of age (t=1.804) and sex (χ2=1.975) between two groups was not significant (P>0.05). The examinations of fundus fluorescein angiography (FFA), CDFI and digital substraction angiography (DSA) were performed before, 1 week and 6 months after treatment. The following parameters were recorded: arm-retinal circulation time (A-Rct), peak systolic velocity (PSV), end-diastolic velocity (EDV), and resistance index (RI) in the ophthalmic artery (OA) and central retinal artery (CRA), and the best corrected visual acuity (BCVA).ResultsThere was no significant differences in A-Rct (t=1.354) and BCVA (t=0.376) between the two groups before treatment (P>0.05). Also, there was no significant differences in PSV (t=−0.294, −2.446), EDV (t=0.141, −0.305), and RI (t=−0.222, −0.694) of OA and CRA between the two groups before treatment before treatment (P>0.05). Compared with the medicine therapy group, the lower A-Rct was found in the CAS group at different time points after the treatment. The difference was significant on 1 week after treatment (t=−3.205, P<0.05), but not on 6 months after treatment (t=1.345, P>0.05). The BCVA of eyes in the two groups were increasing with the extending of time of therapy. Compared with the medicine therapy group, the better BCVA was found in the CAS group at different time points after the treatment (t=0.800, 1.527; P<0.05). Compared with the medicine therapy group, the higher PSV, EDV and lower RI of OA and CRA were found in the CAS group at different time points after the treatment. (P<0.05).ConclusionCompared with conventional medicine therapy, CAS shows earlier effects in improving ocular hemodynamics for IOP patients with carotid artery stenosis, which benefits visual function improvement of the patients.
ObjectiveTo investigate the relationship between retinal vessel diameters and cerebral infarction of carotid artery stenosis patients. MethodsEighty-seven patients (174 eyes) with carotid stenosis were included in this study. There were 49 males and 38 females, with an average age of (65.25±7.85) years. Thirty-four patients were suffered from cerebral infarction (cerebral infarction group), and the other 53 patients had no cerebral infarction (control group). There was no significant difference in age (t=1.916), male rate (χ2=0.142) and carotid stenosis extent (χ2=0.785) between the two groups (P=0.059, 0.706, 0.675). All patients underwent color fundus photography after mydriasis. Retinal vascular caliber measurements were performed using IVAN software. The main parameters were central retinal artery diameter (central retinal artery equivalent, CRAE), the diameter of the central retinal vein (central retinal vein equivalent, CRVE) and the retinal arteriole to venular ratio (AVR). The relationship between retinal vessel diameter and cerebral vascular disease were analyzed with logistic regression analysis. ResultsIn cerebral infarction group, CRVE, CRAE and AVR ratios were (132.90±20.67) μm, (243.47±43.92) μm and 0.56±0.10, while the control group was (145.26±21.59) μm, (224.99±32.35) μm and 0.68±0.13 respectively. There were significant differences between the two groups (t=-2.648, 2.257, -4.631; P < 0.05). After correction for risk factors, such as age, smoking history, CRAE reduction and CRVE increases were significantly correlated with cerebral infarction. ConclusionCRAE reduction and CRVE increases are risk factors of cerebral infarction in patients with carotid stenosis, and it is useful in the prediction.
ObjectiveTo observe the prevalence of ocular ischemic appearance (OIA) associated with carotid artery stenosis, and to explore the correlation between the ocular ischemic appearance and the carotid stenosis degree and location. MethodsA total of 132 patients with carotid artery stenosis diagnosed by color Doppler ultrasound and CT angiography were enrolled in this prospective study. The carotid stenosis degree and location were identified. The ophthalmic symptoms was inquired. The corrected vision, diopter, intraocular pressure, slit lamp microscope and fundus examination were used to determine if OIA exists. The correlation between the OIA and the carotid stenosis degree and location were analyzed. The carotid stenosis degree was divided into 4 types: mild (≤50%), moderate (<50% but ≤75%), severe (<75% but ≤99%) and occlusion (100%). ResultsThe distribution of carotid stenosis degree as follow: mild in 16 patients (12.1%), moderate in 46 patients (34.8%), severe in 50 patients (37.9%) and occlusion in 20 patients (15.2%). The stenosis located in the external carotid artery in 21 patients (15.9%), in internal carotid artery in 46 patients (34.8%), in crotch of extracranial internal carotid artery in 55 patients (41.7%), and in common carotid artery in 10 patients (7.6%). There were 54 patients (40.9%) with ocular ischemic diseases, which including retinal arterial obstruction (5 patients, 9.2%), retina change of venous stasis (13 patients, 24.1%), neovascular glaucoma (7 patients, 13.0%), ischemic optic neuropathy (19 patients, 35.2%), ocular ischemia syndrome (10 patients, 18.5%). The ophthalmic symptoms included transient amaurosis, decreased visual acuity, eye and periorbital pain, retinal hemorrhage and exudation, diplopia, rubeosis iridis and increased intraocular pressure. There was highly positive correlation between the carotid stenosis degree and OIA (r=0.287, P=0.018). There was no correlation between the carotid stenosis location and OIA (P>0.05). Conclusion40.9% carotid stenosis patients has OIA. There is relationship between the carotid stenosis degree and OIA, but carotid stenosis location showed no correlation with OIA.