Objective To detect the value of three-dimensional (3D) ultrasound diagnosis in common ocular fundus diseases. Methods Two-dimensional (2D) images of 38 patients with common ocular fundus diseases were three-dimensionally reconstructed via 3D ultrasound workstation. The 3D images reflecting the ocular diseases were analyzed. Result In 38 patients with common ocular fundus diseases, there was vitreous hemorrhage in 16 patients, retinal detachment in 12, choroidal detachment in 5, and intraocular space occupying lesion in 5. Compared with the 2D images, 3D reconstructed images reflect the lesions more intuitionistically, displayed the relationship between the lesions and the peripheral tissues more clearly, and revealed the blood flow more specifically. During a scanning examination, 3D reconstructed technology provided the diagnostic information of section of X, Y and Z axises simultaneously which shortened the time of examination; the condition of any point of lesions and the relation between the lesion and the peripheral tissues could be gotten by the tools like cut and chop provided by 3D imaging software itself, which avoided detecting the same lesion with different angles and lays and proved the diagnostic efficacy. Conclusions 3D ultrasound diagnosis is better than 2D in diagnosis of vitreous, retina, choroid, and intraocular space occupying lesion. 3D ultrasound diagnosis is a complementarity for the 2D one, and the Z axis changes the former observational angles which may provide the new way of precise diagnosis. (Chin J Ocul Fundus Dis, 2005, 21: 381-383)
Objective To observe the changes of intraocular pressure (IOP) after intravitreous injection wih triamcinolone acetonide (TA) and their affected factors. Methods The clinical data of 125 patients (125eyes) who had undergone intravitreous injection with TA were retrospectively analyzed. The patients (52 males and 73 females) aged from 17 to 83 years with the average age of 56.5. There were 49 patient (39.2%) with diabetic retinopathy (DR), 56 (44.8%) with retinal vein occlusion (RVO), and 20 (16.0%) with exudative age-related macular degeneration (AMD). One day before the treatment, IOP was measured by Goldmann applanation tonometry, and the basic IOP was 7~31 mm Hg (1 mm Hg=0.133 kPa) and the average IOP was (14.69plusmn;3.72) mm Hg. The patients were divided into two groups according to the basic IOP:below 15 mm Hg group (n=64) and 15 mm Hg or above group (n=61). All of the patients underwent intravitreous injection with 4mg TA. IOP was measured 1 day, 3 days, 1 week, 2 weeks, and 1 month after the treatment in the same way, respectively, and later was measured once every 1 month. The follow-up period was 3~21 months with the mean of 5 months. The elevation of IOP would be defined as the pressure of 21mmHg or higher. The changes of IOP in patients before and after the treatment, and with different diseases and ages were analyzed. Results Thirty-six patients (28.8%) had elevation of IOP after the treatment, out of whom 97.2% had the elevation within 3 months after the injection and decreased to the basic level 7 months after the injection. In these patients, there were 11 (17.19%) in the below 15 mm Hg group and 25 (40.98%) in 15 mm Hg or above group, and the difference between the two groups was statistically significant (P<0.01). During the followup period, the mean maximum IOP was (20.09plusmn;7.58) mmHg, which was 5.43 mmHg higher than that before the treatment(P<0.001). The mean maximum IOP of 53 patients (42.4%) after the treatment was 5 mm Hg higher than that before the treatment. The mean maximum IOP during the followup period was (18.19plusmn;4.73)mmHg in DR group,(22.50plusmn;9.30)mmHg in RVO group, and(18.12plusmn;6.09)mmHg in AMD group. The occurrence of the elevation of IOP in RVO group was obviously higher than that in the other 2 groups (P<0.01). The result of regression analysis showed that age was correlative with the elevation of IOP after the treatment: more risks of occurrence of high IOP were found in younger patients (P=0.000). Conclusion Elevation of IOP after intravitreous injection with TA is common, which is correlative with the basic IOP, age, and pathogeny. After the intravitreous injection with TA, the elevation of IOP often occurs in patients with high basic IOP before treatment, younger age, and RVO. (Chin J Ocul Fundus Dis, 2007, 23: 115-117)
Objective To explore the ocular clinical features in patients with cranial venous sinus thrombosis (CVST). Methods The clinical data from 118 inpatients with CVST diagnosed by digital subtraction angiography (DSA).The patients included 53 males and 65 females with the sexual rate of1 :1.2. The initial onset age of the patients ranged from 15 to 67; 20-45 are the most common onset ages, and 30-40 reached the peak. The CVST patients were divided into 3 groups a c cording to the onset styles, including acute onset (within 2 days), subacute ons et (2 days to 1 month), and chronic onset (more than 1 month). The features of o cular and systemic manifestations was analyzed. A total of 58 out of 118 patient s with CVST were followed up for about 1 year after the diagnosis and treatment. Results Among the 118 patients with CVST, 25 (21.2%) had the ocular symptoms as the initial onset, 36 (305%) had ocular syndrome with other symptoms, and 57 (48.3%) had non ocular symptoms. There was no statistical significance among each group. The most common chief complains were the blurred and decreased vision (in 61 eyes, occupying 85.9% of all the chief complains). The most common symptom was papilloedema (in 57 eyes, accounting for 48.3% of all the patients with CVST). In 58 follow-up patients, 13 (22.4%) had serious visual decrease due to the optic atrophy. All the ocular manifestations related to the intracranial hyper tension caused by CVST. Conclusions In patients with CVST, 1/3 have ocular symptoms, and 1/5 have ocular symptoms as the initial manifestation. Visual decrease and papilloedema are the common symptoms in patients with CVST. We should especially advert to the patients with intracranial hypertension with unknown origins. (Chin J Ocul Fundus,dis,2006,22:373-375)