ObjectiveTo observe the clinical effect of super-selective ophthalmic artery or selective carotid artery thrombolytic therapy for central retinal artery occlusion (CRAO). MethodsTwelve CRAO patients (12 eyes) were enrolled in this study. The patients included 7 males and 5 females. The age was ranged from 19 to 68 years old, with an average of (50.0±3.5) years. The disease duration was from 8 to 72 hours, with a mean of 18 hours. All the patients were received the treatment of super-selective ophthalmic artery or selective carotid artery thrombolysis with urokinase (total 0.20-0.4 million U) and injection of papaverine 30 mg. Five patients received the treatment of super-selective ophthalmic artery thrombolytic therapy, 7 patients received the treatment of selective carotid artery thrombolytic therapy (4 patients because of the financial issues, 3 patients because of thin ophthalmic artery). According to the visual acuity of post-treatment and pre-treatment, the therapeutic effects on vision were defined as effective markedly (improving three lines or more), effective (improving two lines) and no effect (no change or a decline). According to the arm-retinal circulation time (A-Rct) and filling time of retinal artery and its branches (FT) on fluorescence fundus angiography (FFA), the therapeutic effects on retinal circulation were defined as effective markedly (A-Rct 15 s, FT 2 s), effective (A-Rct was improved but in the range of 16-20 s, FT was in 3-8 s) and no effect (A-Rct was improved but 21 s, FT 9 s). ResultsThe vision changes showed effective markedly in 5 eyes (41.7%), effective in 5 eyes (41.7%), no effect in 2 eyes (16.6%). The total therapeutic efficiency on vision was 83.4%. The retinal circulation was improved in all eyes after treatment, including effective markedly in 8 eyes (67.0%), effective in 4 eyes (33.0%). The total therapeutic efficiency on retinal circulation was 100.0%. No complications occurred in these 12 patients during the treatment or follow-up, such as puncture site hematoma, intracranial hemorrhage, cerebral embolism, eye movement abnormalities, retinal and vitreous hemorrhage. ConclusionSuper-selective ophthalmic artery and selective carotid artery thrombolytic therapy were effective in the treatment of CRAO.
ObjectiveTo observe the clinical effect of the ophthalmic artery branch retrograde interventional therapy for central retinal artery occlusion (CRAO). MethodsFourteen CRAO patients (14 eyes) were enrolled in this study, including 8 males and 6 females. The age was ranged from 35 to 80 years old,with an average of (56.7±20.3) years. The duration of occurrence after the onset was 9 to 72 hours, with a mean of 22 hours. There were 4 eyes with vision of no light perception, 5 eyes with light perception and 5 eyes with hand movement. The intraocular pressure was ranged from 14-20 mmHg (1 mmHg=0.133 kPa), with an average of 19 mmHg. All the patients received the treatment of ophthalmic artery branch retrograde interventional therapy according to the indications and contraindications of thrombolytic therapy in acute cerebral infraction patients. Micro catheters was inserted into the exposed arteries from a skin incision below the eyebrow under guidance of digital subtraction angiography (DSA), urokinase (total 0.4 million U) and papaverine 30 mg were injected into the arteries. After artery thrombolysis, the changes of DSA, filling time of retinal artery and its branches on fluorescence fundus angiography (FFA) within 48 hours and the visual acuity were observed. According to the visual acuity of post-treatment and pre-treatment, the therapeutic effects on vision were defined as effective markedly (improving 3 lines or more), effective (improving 2 lines) and no effect (change within 1 line or a decline). According to the arm-retinal circulation time (A-Rct) and filling time of retinal artery and its branches (FT) on fluorescence fundus angiography (FFA), the therapeutic effects on retinal circulation were defined as effective markedly (A-Rct 15 s, FT 2 s), effective (A-Rct was improved but in the range of 16-20 s, FT was in 3-8 s) and no effect (A-Rct was improved but 21 s, FT 9 s). The follow up ranged from 5 to 21days, with a mean of 6 days. The related local or systemic complications were recorded. ResultsOphthalmic arterial catheterization under DSA was successful in all 14 eyes. After intermittent injection of drugs, ophthalmic artery and internal carotid artery displayed good images in DSA. The results showed enlargement of ophthalmic artery and its branches after injection of thrombolytic drugs by micro catheters. The circulation time in ophthalmic artery is speed up for 2 s before thrombolysis in 5 eyes, 3 s in 6 eyes, and 4 s in 3 eyes. Within 48 hours after thrombolysis treatment, the filling time of retinal artery and its branches on FFA was significantly increased than that of before interventional therapy. The retinal circulation was effective markedly in 8 eyes (57.1%), effective in 4 eyes (28.6%) and no effect in 2 eyes (14.3%). The vision changes showed effective markedly in 6 eyes (42.9%), effective in 6 eyes (42.9%), no effect in 2 eyes (14.2%). There was no abnormal eye movements, vitreous hemorrhage and incision hematoma, intracranial hemorrhage, cerebral embolism, and other local and systemic adverse effectives during the follow-up. ConclusionsThe ophthalmic artery branch retrograde interventional therapy in the treatment for CRAO can improve retinal circulation and vision. And there is no related local or systemic complications.
Objective To observe the clinical effect of intravenous thrombolytic therapy for central retinal artery occlusion (CRAO) with poor effect after the treatment of arterial thrombolytic therapy. Methods Twenty-four CRAO patients (24 eyes) with poor effect after the treatment of arterial thrombolytic therapy were enrolled in this study. There were 11 males and 13 females. The age was ranged from 35 to 80 years, with the mean age of (56.7±15.6) years. There were 11 right eyes and 13 left eyes. The visual acuity was tested by standard visual acuity chart. The arm-retinal circulation time (A-Rct) and the filling time of retinal artery and its branches (FT) were detected by fluorescein fundus angiography (FFA). The visual acuity was ranged from light sensation to 0.5, with the average of 0.04±0.012. The A-Rct was ranged from 18.0 s to 35.0 s, with the mean of (29.7±5.8) s. The FT was ranged from 4.0 s to 16.0 s, with the mean of (12.9±2.3) s. All patients were treated with urokinase intravenous thrombolytic therapy. The dosage of urokinase was 3000 U/kg, 2 times/d, adding 250 ml of 0.9% sodium chloride intravenous drip, 2 times between 8 - 10 h, and continuous treatment of FFA after 5 days. Comparative analysis was performed on the visual acuity of the patients before and after treatment, and the changes of A-Rct and FT. Results After intravenous thrombolytic therapy, the A-Rct was ranged from 16.0 s to 34.0 s, with the mean of (22.4±5.5) s. Among 24 eyes, the A-Rct was 27.0 - 34.0 s in 4 eyes (16.67%), 18.0 - 26.0 s in 11 eyes (45.83%); 16.0 - 17.0 s in 9 eyes (37.50%). The FT was ranged from 2.4 s to 16.0 s, with the mean of (7.4±2.6) s. Compared with before intravenous thrombolytic therapy, the A-Rct was shortened by 7.3 s and the FT was shortened by 5.5 s with the significant differences (χ2=24.6, 24.9; P<0.01). After intravenous thrombolytic therapy, the visual acuity was ranged from light sensation to 0.6, with the average of 0.08±0.011. There were 1 eye with vision of light perception (4.17%), 8 eyes with hand movement/20 cm (33.33%), 11 eyes with 0.02 - 0.05 (45.83%), 2 eyes with 0.1 - 0.2 (8.33%), 1 eye with 0.5 (4.17%) and 1 eye with 0.6 (4.17%). The visual acuity was improved in 19 eyes (79.17%). The difference of visual acuity before and after intravenous thrombolytic therapy was significant (χ2=7.99, P<0.05). There was no local and systemic adverse effects during and after treatment. Conclusion Intravenous thrombolytic therapy for CRAO with poor effect after the treatment of arterial thrombolytic therapy can further improve the circulation of retinal artery and visual acuity.
ObjectiveTo observe the effect of interventional thrombolytic therapy for central retinal artery occlusion (CRAO) with ipsilateral internal carotid artery occlusion via supratrochlear artery retrogradely or external carotid artery anterogradely.MethodsNine CRAO patients (9 eyes) were enrolled in this study, including 5 males and 4 females. The mean age was (45.2±18.1) years. The mean onset duration was 24 hours. There were 4 eyes with vision of no light perception, 3 eyes with light perception and 2 eyes with hand movement. Fundus fluorescein angiography (FFA) examination showed that the retinal artery was filled with delayed fluorescence. The peak of fluorescence was seen in the anterior part of the artery, and some of the eyes showed retrograde filling. The arm-retinal circulation time (A-Rct) was ≥35 s in 4 eyes, ≥35 s - <25 s in 5 eyes. The filling time of retinal artery and its branches (FT) was ≥15 s in 2 eyes, ≥12 s - <15 s in 3 eyes, ≥9 s - <12 s in 4 eyes. All the patients received the treatment of interventional thrombolytic therapy via supratrochlear artery retrogradely (8 eyes) or external carotid artery anterogradely (1 eye) according to the indications and contraindications of thrombolytic therapy in acute cerebral infraction patients. Urokinase (0.4 million U in total) was intermittently injected into the arteries. After artery thrombolysis, the changes of digital subtraction angiography (DSA), filling time of retinal artery and its branches on FFA within 24 hours and the visual acuity were observed. According to the A-Rct and FT on FFA, the therapeutic effects on retinal circulation were defined as effective markedly (A-Rct≤15 s, FT≤2 s) , effective (A-Rct was improved but in the range of 16 - 20 s, FT was in 3 - 8 s) and no effect (A-Rct was improved but ≥21 s, FT≥9 s). The related local or systemic complications were recorded.ResultsAfter the injection of urokinase into the catheter, the ophthalmic artery and its branches were increased in 6 eyes (66.7%), and the development of the eye ring was significantly more than that of the eyes before thrombolysis. The circulation time in ophthalmic artery was speeded up for 2 s before thrombolysis in 3 eyes, 3 s in 3 eyes, and 4 s in 2 eyes. Within 24 hours after thrombolysis treatment, the A-Rct was significantly decreased than that of before interventional therapy. The retinal circulation was effective markedly in 4 eyes (44.4%), effective in 4 eyes (44.4%) and no effect in 1 eyes (11.2%) . The vision was improved 3 lines in 4 eyes (44.4%), 2 lines in 3 eyes (33.3%), 1 line in 1 eye (11.2%) and no change in 1 eye (11.2%). There were no abnormal eye movements, vitreous hemorrhage and incision hematoma, intracranial hemorrhage, cerebral embolism, and other local and systemic adverse effectives during the follow-up.ConclusionsThe interventional thrombolytic therapy via supratrochlear artery retrogradely or external carotid artery anterogradely for CRAO with the ipsilateral internal carotid artery occlusion can improve retinal circulation and vision. There are no related local or systemic complications.
ObjectiveTo compare the clinical effects of urokinase thrombolytic therapy for optic artery occlusion (OAO) and retinal artery occlusion (RAO) caused by facial microinjection with hyaluronic acid and spontaneous RAO.MethodsFrom January 2014 to February 2018, 22 eyes of 22 patients with OAO and RAO caused by facial microinjection of hyaluronic acid who received treatment in Xi'an Fourth Hospital were enrolled in this retrospective study (hyaluronic acid group). Twenty-two eyes of 22 patients with spontaneous RAO were selected as the control group. The BCVA examination was performed using the international standard visual acuity chart, which was converted into logMAR visual acuity. FFA was used to measure arm-retinal circulation time (A-Rct) and filling time of retinal artery and its branches (FT). Meanwhile, MRI examination was performed. There were significant differences in age and FT between the two groups (t=14.840, 3.263; P=0.000, 0.003). The differecens of logMAR visual acuity, onset time and A-Rct were not statistically significant between the two groups (t=0.461, 0.107, 1.101; P=0.647, 0.915, 0.277). All patients underwent urokinase thrombolysis after exclusion of thrombolytic therapy. Among the patients in the hyaluronic acid group and control group, there were 6 patients of retrograde ophthalmic thrombolysis via the superior pulchlear artery, 6 patients of retrograde ophthalmic thrombolysis via the internal carotid artery, and 10 patients of intravenous thrombolysis. FFA was reviewed 24 h after treatment, and A-Rct and FT were recorded. Visual acuity was reviewed 30 days after treatment. The occurrence of adverse reactions during and after treatment were observed. The changes of logMAR visual acuity, A-Rct and FT before and after treatment were compared between the two groups using t-test.ResultsAt 24 h after treatment, the A-Rct and FT of the hyaluronic acid group were 21.05±3.42 s and 5.05±2.52 s, which were significantly shorter than before treatment (t=4.569, 2.730; P=0.000, 0.000); the A-Rct and FT in the control group were 19.55±4.14 s and 2.55±0.91 s, which were significantly shorter than before treatment (t=4.114, 7.601; P=0.000, 0.000). There was no significant difference in A-Rct between the two groups at 24 h after treatment (t=1.311, P=0.197). The FT difference was statistically significant between the two groups at 24 h after treatment (t=4.382, P=0.000). There was no significant difference in the shortening time of A-Rct and FT between the two groups (t=0.330, 0.510; P=0.743, 0.613). At 30 days after treatment, the logMAR visual acuity in the hyaluronic acid group and the control group were 0.62±0.32 and 0.43±0.17, which were significantly higher than those before treatment (t=2.289, 5.169; P=0.029, 0.000). The difference of logMAR visual acuity between the two groups after treatment was statistically significant (t=2.872, P=0.008). The difference in logMAR visual acuity before and after treatment between the two groups was statistically significant (t=2.239, P=0.025). No ocular or systemic adverse reactions occurred during or after treatment in all patients. ConclusionsUrokinase thrombolytic therapy for OAO and RAO caused by facial microinjection with hyaluronic acid and spontaneous RAO is safe and effective, with shortening A-Rct, FT and improving visual acuity. However, the improvement of visual acuity after treatment of OAO and RAO caused by facial microinjection with hyaluronic acid is worse than that of spontaneous RAO.
ObjectiveTo observe the efficacy and safety of urokinase arterial thrombolysis in the treatment of central retinal artery occlusion (CRAO) at different time window.MethodsA retrospective study. From January 2014 to November 2019, 157 eyes (157 CRAO patients) in the Xi’an People's Hospital (Xi’an Fourth Hospital) were included in the study. There were 120 males and 37 females, with the average age of 54.87±12.12 years. The mean onset time was 65.66±67.44 h. All patients were tested with BCVA using international standard visual acuity chart, and the results were converted into logMAR visual acuity record. The arm-retinal circulation time (A-Rct) and the filling time (FT) of retinal arterial trunk-terminal filling time were measured by FFA. The mean logMAR BCVA was 2.44±0.46, the mean A-Rct and FT were 27.72±9.78 and 13.58±14.92 s respectively. According to the time window, the patients were divided into the onset 3-72 h group and the onset 73-240 h group, which were 115 patients and 42 patients respectively. There were no statistically significant difference between the 3-72 h group and the 73-240 h group in age, A-Rct and LogMR BCVA before treatment (χ2=-0.197, -1.242, -8.990; P=0.844, 0.369, 0.369); the difference was statistically significant in FT comparison (χ2=-3.652, P=0.000). Urokinase artery thrombolytic therapy was performed at different time window of 3-24 h, 25-72 h, 73-96 h, 97-120 h, 121-240 h after the onset of onset. Age and A-Rct of patients with different treatment time windows were compared, and the differences were not statistically significant (χ2=6.588, 6.679; P=0.253, 0.246).In comparison of FT and logMAR BCVA, the difference was statistically significant (χ2 =30.150, 71.378; P=0.000, 0.000). FFA was rechecked 24 hours after treatment, BCVA was rechecked 30 days after treatment. The changes of A-Rct, FT and BCVA before and after treatment were compared and analyzed. The occurrence of adverse reactions during and after treatment were observed. The two groups of measurement data were compared. The t test was used for those with normal distribution and χ2 test was used for those with non-normal distribution. Spearman correlation analysis was used to analyze the correlation between onset time and the difference of A-Rct, FT shortening time and logMAR BCVA after treatment.ResultsAt 24 h after CRAO treatment, A-Rct and FT of 157 cases were 19.64±6.50 and 6.48±7.36 s respectively, which were significantly shorter than those before treatment, and the differences were statistically significant (χ2=-16.236, -14.703; P=0.000, 0.000). The logMAR BCVA at 30 d after treatment was 1.72±0.76, which was significantly higher than that before treatment. The difference was statistically significant (χ2=-14.460, P=0.000). After CRAO urokinase arterial thrombolysis at different time window, there were statistically significant differences in A-Rct shortening time, FT shortening time, and logMAR BCVA difference (χ2=12.408, 24.200, 104.388; P=0.030, 0.000, 0.000). There was no statistically significant difference between the 3-72 h group and the 73-240 h group (χ2 =-1.042, P=0.297) in shortening time of A-Rct after treatment. The difference of FT shortening time was statistically significant (χ2=-3.581, P=0.000). The difference of logMAR BCVA was statistically significant (χ2=-9.905, P=0.000). The results of Spearman correlation analysis showed that there was no correlation between the onset time and the shortening time of A-Rct and FT after treatment (rp=-0.040, -0.081; P=0.436, 0.115), and negative correlation with the logMAR BCVA difference (rp=-0.486, P=0.000). One case of intracranial hemorrhage occurred after treatment, and it improved after dehydration to reduce cerebral edema, scavenging free radicals and brain protection.ConclusionsUrokinase arterial thrombolytic therapy is effective for CRAO within time window of 3-240 h, A-Rct, FT and LogMRA BCVA are all improved. However, with the prolongation of thrombolytic therapy time window, the therapeutic effect of urokinase arterial thrombolytic therapy is decreased. The therapeutic effect of Urokinase arterial thrombolytic therapy was better within 72 h.